Algebraic Geometry

J.S. Milne

Version 5.22January 13, 2012

These notes are an introduction to the theory of algebraic varieties. In contrast to mostsuch accounts they study abstract algebraic varieties, and not just subvarieties of affine andprojective space. This approach leads more naturally into scheme theory.

BibTeX information

@misc{milneAG,

author={Milne, James S.},

title={Algebraic Geometry (v5.22)},

year={2012},

note={Available at www.jmilne.org/math/},

pages={260}

}

v2.01 (August 24, 1996). First version on the web.v3.01 (June 13, 1998).v4.00 (October 30, 2003). Fixed errors; many minor revisions; added exercises; added two

sections/chapters; 206 pages.v5.00 (February 20, 2005). Heavily revised; most numbering changed; 227 pages.v5.10 (March 19, 2008). Minor fixes; TEXstyle changed, so page numbers changed; 241

pages.v5.20 (September 14, 2009). Minor corrections; revised Chapters 1, 11, 16; 245 pages.v5.21 (March 31, 2011). Minor changes; changed TEXstyle; 258 pages.v5.22 (January 13, 2012). Minor fixes; 260 pages.

Available at www.jmilne.org/math/Please send comments and corrections to me at the address on my web page.

The photograph is of Lake Sylvan, New Zealand.

Copyright c 1996, 1998, 2003, 2005, 2008, 2009, 2011, 2012 J.S. Milne.Single paper copies for noncommercial personal use may be made without explicit permis-sion from the copyright holder.

Contents

Contents 3Notations 6; Prerequisites 6; References 6; Acknowledgements 6

1 Preliminaries 11Rings and algebras 11; Ideals 11; Noetherian rings 13; Unique factorization 16; Polynomialrings 18; Integrality 19; Direct limits (summary) 21; Rings of fractions 22; Tensor Prod-ucts 25; Categories and functors 28; Algorithms for polynomials 31; Exercises 37

2 Algebraic Sets 39Definition of an algebraic set 39; The Hilbert basis theorem 40; The Zariski topology 41;The Hilbert Nullstellensatz 42; The correspondence between algebraic sets and ideals 43;Finding the radical of an ideal 46; The Zariski topology on an algebraic set 46; The coor-dinate ring of an algebraic set 47; Irreducible algebraic sets 48; Dimension 50; Exercises52

3 Affine Algebraic Varieties 55Ringed spaces 55; The ringed space structure on an algebraic set 57; Morphisms of ringedspaces 60; Affine algebraic varieties 60; The category of affine algebraic varieties 61;Explicit description of morphisms of affine varieties 63; Subvarieties 65; Properties of theregular map defined by specm.˛/ 66; Affine space without coordinates 67; Exercises 68

4 Algebraic Varieties 71Algebraic prevarieties 71; Regular maps 72; Algebraic varieties 73; Maps from varieties toaffine varieties 74; Subvarieties 75; Prevarieties obtained by patching 76; Products of vari-eties 76; The separation axiom revisited 81; Fibred products 84; Dimension 85; Birationalequivalence 86; Dominant maps 87; Algebraic varieties as a functors 87; Exercises 89

5 Local Study 91Tangent spaces to plane curves 91; Tangent cones to plane curves 93; The local ring at apoint on a curve 93; Tangent spaces of subvarieties of Am 94; The differential of a regularmap 96; Etale maps 97; Intrinsic definition of the tangent space 99; Nonsingular points102; Nonsingularity and regularity 103; Nonsingularity and normality 104; Etale neigh-bourhoods 105; Smooth maps 107; Dual numbers and derivations 108; Tangent cones 111;Exercises 113

6 Projective Varieties 115Algebraic subsets of Pn 115; The Zariski topology on Pn 118; Closed subsets of An andPn 119; The hyperplane at infinity 119; Pn is an algebraic variety 120; The homogeneous

3

coordinate ring of a subvariety of Pn 122; Regular functions on a projective variety 123;Morphisms from projective varieties 124; Examples of regular maps of projective vari-eties 125; Projective space without coordinates 130; Grassmann varieties 130; Bezout’stheorem 134; Hilbert polynomials (sketch) 135; Exercises 136

7 Complete varieties 137Definition and basic properties 137; Projective varieties are complete 139; Eliminationtheory 140; The rigidity theorem 142; Theorems of Chow 143; Nagata’s Embedding The-orem 144; Exercises 144

8 Finite Maps 145Definition and basic properties 145; Noether Normalization Theorem 149; Zariski’s maintheorem 150; The base change of a finite map 152; Proper maps 152; Exercises 154

9 Dimension Theory 155Affine varieties 155; Projective varieties 162

10 Regular Maps and Their Fibres 165Constructible sets 165; Orbits of group actions 168; The fibres of morphisms 170; Thefibres of finite maps 172; Flat maps 173; Lines on surfaces 174; Stein factorization 180;Exercises 180

11 Algebraic spaces; geometry over an arbitrary field 181Preliminaries 181; Affine algebraic spaces 185; Affine algebraic varieties. 186; Algebraicspaces; algebraic varieties. 187; Local study 192; Projective varieties. 193; Completevarieties. 194; Normal varieties; Finite maps. 194; Dimension theory 194; Regular mapsand their fibres 194; Algebraic groups 194; Exercises 194

12 Divisors and Intersection Theory 195Divisors 195; Intersection theory. 196; Exercises 201

13 Coherent Sheaves; Invertible Sheaves 203Coherent sheaves 203; Invertible sheaves. 205; Invertible sheaves and divisors. 206; Directimages and inverse images of coherent sheaves. 208; Principal bundles 209

14 Differentials (Outline) 211

15 Algebraic Varieties over the Complex Numbers 215

16 Descent Theory 219Models 219; Fixed fields 219; Descending subspaces of vector spaces 220; Descendingsubvarieties and morphisms 222; Galois descent of vector spaces 223; Descent data 224;Galois descent of varieties 228; Weil restriction 229; Generic fibres and specialization 229;Rigid descent 230; Weil’s descent theorems 232; Restatement in terms of group actions234; Faithfully flat descent 236

17 Lefschetz Pencils (Outline) 239Definition 239

18 Algebraic Schemes and Algebraic Spaces 243

4

A Solutions to the exercises 245

B Annotated Bibliography 253

Index 257

QUESTION: If we try to explain to a layman what algebraic geometry is, it seems to me thatthe title of the old book of Enriques is still adequate: Geometrical Theory of Equations....GROTHENDIECK: Yes! but your “layman” should know what a system of algebraic equa-tions is. This would cost years of study to Plato.

5

Notations

We use the standard (Bourbaki) notations: ND f0;1;2; : : :g, ZD ring of integers, RD fieldof real numbers, C D field of complex numbers, Fp D Z=pZ D field of p elements, p aprime number. Given an equivalence relation, Œ�� denotes the equivalence class containing�. A family of elements of a set A indexed by a second set I , denoted .ai /i2I , is a functioni 7! ai WI ! A.

A field k is said to be separably closed if it has no finite separable extensions of degree> 1. We use ksep and kal to denote separable and algebraic closures of k respectively.

All rings will be commutative with 1, and homomorphisms of rings are required to map1 to 1. For a ring A, A� is the group of units in A:

A� D fa 2 A j there exists a b 2 A such that ab D 1g:

We use Gothic (fraktur) letters for ideals:

a b c m n p q A B C M N P Qa b c m n p q A B C M N P Q

XdefD Y X is defined to be Y , or equals Y by definition;

X � Y X is a subset of Y (not necessarily proper, i.e., X may equal Y );X � Y X and Y are isomorphic;X ' Y X and Y are canonically isomorphic (or there is a given or unique isomorphism).

Prerequisites

The reader is assumed to be familiar with the basic objects of algebra, namely, rings, mod-ules, fields, and so on, and with transcendental extensions of fields (FT, Chapter 8).

References

Atiyah and MacDonald 1969: Introduction to Commutative Algebra, Addison-Wesley.Cox et al. 1992: Varieties, and Algorithms, Springer.FT: Milne, J.S., Fields and Galois Theory, v4.22, 2011.CA: Milne, J.S., Commutative Algebra, v2.22, 2011.Hartshorne 1977: Algebraic Geometry, Springer.Mumford 1999: The Red Book of Varieties and Schemes, Springer.Shafarevich 1994: Basic Algebraic Geometry, Springer.

For other references, see the annotated bibliography at the end.

Acknowledgements

I thank the following for providing corrections and comments on earlier versions of thesenotes: Sandeep Chellapilla, Rankeya Datta, Umesh V. Dubey, Shalom Feigelstock, TonyFeng, B.J. Franklin, Sergei Gelfand, Daniel Gerig, Darij Grinberg, Lucio Guerberoff, GuidoHelmers, Florian Herzig, Christian Hirsch, Cheuk-Man Hwang, Jasper Loy Jiabao, LarsKindler, John Miller, Joaquin Rodrigues, Sean Rostami, David Rufino, Hossein Sabzrou,Jyoti Prakash Saha, Tom Savage, Nguyen Quoc Thang, Bhupendra Nath Tiwari, Soli Vishkaut-san, Dennis Bouke Westra, and others.

6

Introduction

There is almost nothing left to discover ingeometry.Descartes, March 26, 1619

Just as the starting point of linear algebra is the study of the solutions of systems oflinear equations,

nXjD1

aijXj D bi ; i D 1; : : : ;m; (1)

the starting point for algebraic geometry is the study of the solutions of systems of polyno-mial equations,

fi .X1; : : : ;Xn/D 0; i D 1; : : : ;m; fi 2 kŒX1; : : : ;Xn�:

Note immediately one difference between linear equations and polynomial equations: the-orems for linear equations don’t depend on which field k you are working over,1 but thosefor polynomial equations depend on whether or not k is algebraically closed and (to a lesserextent) whether k has characteristic zero.

A better description of algebraic geometry is that it is the study of polynomial functionsand the spaces on which they are defined (algebraic varieties), just as topology is the studyof continuous functions and the spaces on which they are defined (topological spaces),differential topology the study of infinitely differentiable functions and the spaces on whichthey are defined (differentiable manifolds), and so on:

algebraic geometry regular (polynomial) functions algebraic varieties

topology continuous functions topological spaces

differential topology differentiable functions differentiable manifolds

complex analysis analytic (power series) functions complex manifolds.

The approach adopted in this course makes plain the similarities between these differentareas of mathematics. Of course, the polynomial functions form a much less rich class thanthe others, but by restricting our study to polynomials we are able to do calculus over anyfield: we simply define

d

dX

XaiX

iD

XiaiX

i�1:

1For example, suppose that the system (1) has coefficients aij 2 k and that K is a field containing k. Then(1) has a solution in kn if and only if it has a solution in Kn, and the dimension of the space of solutions is thesame for both fields. (Exercise!)

7

8 INTRODUCTION

Moreover, calculations (on a computer) with polynomials are easier than with more generalfunctions.

Consider a nonzero differentiable function f .x;y;z/. In calculus, we learn that theequation

f .x;y;z/D C (2)

defines a surface S in R3, and that the tangent plane to S at a point P D .a;b;c/ hasequation2 �

@f

@x

�P

.x�a/C

�@f

@y

�P

.y�b/C

�@f

@z

�P

.z� c/D 0: (3)

The inverse function theorem says that a differentiable map ˛WS! S 0 of surfaces is a localisomorphism at a point P 2 S if it maps the tangent plane at P isomorphically onto thetangent plane at P 0 D ˛.P /.

Consider a nonzero polynomial f .x;y;z/ with coefficients in a field k. In this course,we shall learn that the equation (2) defines a surface in k3, and we shall use the equation(3) to define the tangent space at a point P on the surface. However, and this is one of theessential differences between algebraic geometry and the other fields, the inverse functiontheorem doesn’t hold in algebraic geometry. One other essential difference is that 1=X isnot the derivative of any rational function of X , and nor is Xnp�1 in characteristic p ¤ 0— these functions can not be integrated in the ring of polynomial functions.

The first ten chapters of the notes form a basic course on algebraic geometry. In thesechapters we generally assume that the ground field is algebraically closed in order to beable to concentrate on the geometry. The remaining chapters treat more advanced topics,and are largely independent of one another except that Chapter 11 should be read first.

The approach to algebraic geometry taken in these notes

In differential geometry it is important to define differentiable manifolds abstractly, i.e., notas submanifolds of some Euclidean space. For example, it is difficult even to make senseof a statement such as “the Gauss curvature of a surface is intrinsic to the surface but theprincipal curvatures are not” without the abstract notion of a surface.

Until the mid 1940s, algebraic geometry was concerned only with algebraic subvarietiesof affine or projective space over algebraically closed fields. Then, in order to give substanceto his proof of the congruence Riemann hypothesis for curves an abelian varieties, Weilwas forced to develop a theory of algebraic geometry for “abstract” algebraic varieties overarbitrary fields,3 but his “foundations” are unsatisfactory in two major respects:

˘ Lacking a topology, his method of patching together affine varieties to form abstractvarieties is clumsy.

˘ His definition of a variety over a base field k is not intrinsic; specifically, he fixessome large “universal” algebraically closed field ˝ and defines an algebraic varietyover k to be an algebraic variety over ˝ with a k-structure.

In the ensuing years, several attempts were made to resolve these difficulties. In 1955,Serre resolved the first by borrowing ideas from complex analysis and defining an algebraicvariety over an algebraically closed field to be a topological space with a sheaf of functions

2Think of S as a level surface for the function f , and note that the equation is that of a plane through.a;b;c/ perpendicular to the gradient vector .Of /P of f at P .

3Weil, Andre. Foundations of algebraic geometry. American Mathematical Society, Providence, R.I. 1946.

9

that is locally affine.4 Then, in the late 1950s Grothendieck resolved all such difficulties byintroducing his theory of schemes.

In these notes, we follow Grothendieck except that, by working only over a base field,we are able to simplify his language by considering only the closed points in the underlyingtopological spaces. In this way, we hope to provide a bridge between the intuition given bydifferential geometry and the abstractions of scheme theory.

4Serre, Jean-Pierre. Faisceaux algebriques coherents. Ann. of Math. (2) 61, (1955). 197–278.

CHAPTER 1Preliminaries

In this chapter, we review some definitions and basic results in commutative algebra andcategory theory, and we derive some algorithms for working in polynomial rings.

Rings and algebras

Let A be a ring. A subring of A is a subset that contains 1A and is closed under addition,multiplication, and the formation of negatives. An A-algebra is a ring B together with ahomomorphism iB WA!B . A homomorphism of A-algebras B! C is a homomorphismof rings 'WB! C such that '.iB.a//D iC .a/ for all a 2 A.

Elements x1; : : : ;xn of an A-algebra B are said to generate it if every element of B canbe expressed as a polynomial in the xi with coefficients in iB.A/, i.e., if the homomorphismof A-algebras AŒX1; : : : ;Xn�! B acting as iA on A and sending Xi to xi is surjective. Wethen write B D .iBA/Œx1; : : : ;xn�.

A ring homomorphism A! B is said to be of finite-type, and B is a finitely generatedA-algebra if B is generated by a finite set of elements as an A-algebra.

A ring homomorphism A! B is finite, and B is a finite1 A-algebra, if B is finitelygenerated as an A-module.

Let k be a field, and let A be a k-algebra. When 1A ¤ 0 in A, the map k ! A isinjective, and we can identify k with its image, i.e., we can regard k as a subring of A.When 1A D 0 in a ring A, then A is the zero ring, i.e., AD f0g.

Let AŒX� be the polynomial ring in the symbol X with coefficients in A. If A is anintegral domain, then deg.fg/ D deg.f /C deg.g/, and it follows that AŒX� is also anintegral domain; moreover, AŒX�� D A�.

Ideals

Let A be a ring. An ideal a in A is a subset such that

(a) a is a subgroup of A regarded as a group under addition;(b) a 2 a, r 2 A) ra 2 a:

The ideal generated by a subset S of A is the intersection of all ideals a containing S— it is easy to verify that this is in fact an ideal, and that it consists of all finite sums of the

1The term “module-finite” is also used.

11

12 1. PRELIMINARIES

formPrisi with ri 2A, si 2 S . The ideal generated by the empty set is the zero ideal f0g.

When S D fs1; s2; : : :g, we shall write .s1; s2; : : :/ for the ideal it generates.Let a and b be ideals in A. The set faCb j a 2 a; b 2 bg is an ideal, denoted by aCb.

The ideal generated by fab j a 2 a; b 2 bg is denoted by ab. Clearly ab consists of all finitesums

Paibi with ai 2 a and bi 2 b, and if a D .a1; : : : ;am/ and b D .b1; : : : ;bn/, then

abD .a1b1; : : : ;aibj ; : : : ;ambn/. Note that

ab� a\b: (4)

The kernel of a homomorphismA!B is an ideal inA. Conversely, for any ideal a inA,the set of cosets of a inA forms a ringA=a, and a 7! aCa is a homomorphism 'WA!A=awhose kernel is a. The map b 7! '�1.b/ is a one-to-one correspondence between the idealsof A=a and the ideals of A containing a.

An ideal p is prime if p¤ A and ab 2 p) a 2 p or b 2 p. Thus p is prime if and onlyif A=p is nonzero and has the property that

ab D 0; b ¤ 0) aD 0;

i.e., A=p is an integral domain. Note that if p is prime and a1 � � �an 2 p, then at least one ofthe ai 2 p.

An ideal m in A is maximal if it is maximal among the proper ideals of A. Thus m ismaximal if and only if A=m is nonzero and has no proper nonzero ideals, and so is a field.Note that

m maximal H) m prime.

The ideals of A�B are all of the form a� b with a and b ideals in A and B . To seethis, note that if c is an ideal in A�B and .a;b/ 2 c, then .a;0/ D .1;0/.a;b/ 2 c and.0;b/D .0;1/.a;b/ 2 c. Therefore, cD a�b with

aD fa j .a;0/ 2 cg; bD fb j .0;b/ 2 cg:

Ideals a and b in A are coprime if aC bD A. When a and b are coprime, there exista 2 a and b 2 b such that aCb D 1. For x;y 2 A, let z D ayCbx; then

z � bx � x moda

z � ay � ymodb;

and so the canonical mapA! A=a�A=b (5)

is surjective. Clearly its kernel is a\b, which contains ab. Let c 2 a\b; then

c D caC cb 2 ab:

Hence, (5) is surjective with kernel ab. This statement extends to finite sets of ideals.

THEOREM 1.1 (CHINESE REMAINDER THEOREM). Let a1; : : : ;an be ideals in a ring A.If ai is coprime to aj whenever i ¤ j , then the map

A! A=a1� � � ��A=an (6)

is surjective, with kernelQ

ai DT

ai .

Noetherian rings 13

PROOF. We have just proved the statement for n D 2. For each i , there exist elementsai 2 a1 and bi 2 ai such that

ai Cbi D 1, all i � 2:

The productQi�2.ai Cbi /D 1, and lies in a1C

Qi�2 ai , and so

a1CY

i�2ai D A:

We can now apply the theorem in the case nD 2 to obtain an element y1 of A such that

y1 � 1 mod a1; y1 � 0 modY

i�2ai :

These conditions imply

y1 � 1 mod a1; y1 � 0 mod aj , all j > 1:

Similarly, there exist elements y2; :::;yn such that

yi � 1 mod ai ; yi � 0 mod aj for j ¤ i:

The element x DPxiyi maps to .x1 moda1; : : : ;xn modan/, which shows that (6) is sur-

jective.It remains to prove that

Tai D

Qai . Obviously

Tai �

Qai . We complete the proof

by induction. This allows us to assume thatQi�2 ai D

Ti�2 ai . We showed above that a1

andQi�2 ai are relatively prime, and so

a1 � .Y

i�2ai /D a1\ .

Yi�2

ai /

by the nD 2 case. Now a1 � .Qi�2 ai /D

Qi�1 ai and

a1\ .Y

i�2ai /D a1\ .

\i�2

ai /D\i�1

ai ;

which completes the proof. 2

Noetherian rings

PROPOSITION 1.2. The following three conditions on a ring A are equivalent:

(a) every ideal in A is finitely generated;(b) every ascending chain of ideals a1 � a2 � �� � eventually becomes constant, i.e., for

some m, am D amC1 D �� � :(c) every nonempty set of ideals in A has a maximal element (i.e., an element not prop-

erly contained in any other ideal in the set).

PROOF. (a) H) (b): If a1 � a2 � �� � is an ascending chain, then aDS

ai is an ideal, andhence has a finite set fa1; : : : ;ang of generators. For some m, all the ai belong am and then

am D amC1 D �� � D a:

14 1. PRELIMINARIES

(b) H) (c): Let ˙ be a nonempty set of ideals in A. If ˙ doesn’t contain a maximalelement, then every ideal in ˙ is properly contained in another ideal in ˙ . Using this, weget an infinite chain of ideals a1 $ a2 $ � � � in ˙ ,2 which violates (b).

(c) H) (a): Let a be an ideal, and let˙ be the set of finitely generated ideals containedin a. Then ˙ is nonempty because it contains the zero ideal, and so it contains a maximalelement cD .a1; : : : ;ar/. If c¤ a, then there exists an element a 2 ar c, and .a1; : : : ;ar ;a/will be a finitely generated ideal in a properly containing c. This contradicts the definitionof c. 2

A ring A is noetherian if it satisfies the equivalent conditions of the proposition. Onapplying (c) to the set of all proper ideals containing a fixed proper ideal, we see that everyproper ideal in a noetherian ring is contained in a maximal ideal. This is, in fact, true forevery ring, but the proof for non-noetherian rings requires Zorn’s lemma (CA 2.1).

A ringA is said to be local if it has exactly one maximal ideal m. Because every nonunitis contained in a maximal ideal, for a local ring A� D Arm.

PROPOSITION 1.3 (NAKAYAMA’S LEMMA). Let A be a local ring with maximal ideal m,and let M be a finitely generated A-module.

(a) If M DmM , then M D 0:(b) If N is a submodule of M such that M DN CmM , then M DN .

PROOF. (a) Suppose that M ¤ 0. Choose a minimal set of generators fe1; : : : ; eng, n � 1,for M , and write

e1 D a1e1C�� �Canen; ai 2m.

Then.1�a1/e1 D a2e2C�� �Canen

and, as .1�a1/ is a unit, e2; : : : ; en generate M , contradicting the minimality of the set.(b) The hypothesis implies that M=N Dm.M=N/, and so M=N D 0. 2

Now let A be a local noetherian ring with maximal ideal m. When we regard m as anA-module, the action of A on m=m2 factors through k D A=m.

COROLLARY 1.4. The elements a1; : : : ;an of m generate m as an ideal if and only if theirresidues modulo m2 generate m=m2 as a vector space over k. In particular, the minimumnumber of generators for the maximal ideal is equal to the dimension of the vector spacem=m2.

PROOF. If a1; : : : ;an generate m, it is obvious that their residues generate m=m2. Con-versely, suppose that their residues generate m=m2, so that mD .a1; : : : ;an/Cm2. BecauseA is noetherian, m is finitely generated, and Nakayama’s lemma, applied with M Dm andN D .a1; : : : ;an/, shows that mD .a1; : : : ;an/. 2

DEFINITION 1.5. Let A be a noetherian ring.2We are using the axiom of dependent choice, which is strictly weaker than the axiom of choice. It can

be stated as follows: let ˙ be a nonempty set, and let R be a subset of ˙ �˙ with the property that, foreach a 2 ˙ , there exists a b 2 ˙ such that .a;b/ 2 R; then there exists a sequence .an/n2N in ˙ such that.an;anC1/ 2R for every n 2 N.

Noetherian rings 15

(a) The height ht.p/ of a prime ideal p in A is the greatest length d of a chain of distinctprime ideals

pD pd � pd�1 � �� � � p0: (7)

(b) The Krull dimension of A is supfht.p/ j p� A; p primeg.

Thus, the Krull dimension of a ring A is the supremum of the lengths of chains ofprime ideals in A (the length of a chain is the number of gaps, so the length of (7) is d ).For example, a field has Krull dimension 0, and conversely an integral domain of Krulldimension 0 is a field. The height of every nonzero prime ideal in a principal ideal domainis 1, and so such a ring has Krull dimension 1 (provided it is not a field).

The height of every prime ideal in a noetherian ring is finite, but the Krull dimensionof the ring may be infinite because it may contain a sequence of prime ideals p1;p2;p3; : : :such that ht.pi / tends to infinity (see Nagata, Local Rings, 1962, Appendix A.1, p203).

DEFINITION 1.6. A local noetherian ring of Krull dimension d is said to be regular if itsmaximal ideal can be generated by d elements.

It follows from Corollary 1.4 that a local noetherian ring is regular if and only if itsKrull dimension is equal to the dimension of the vector space m=m2.

LEMMA 1.7. In a noetherian ring, every set of generators for an ideal contains a finitegenerating subset.

PROOF. Let a be an ideal in a noetherian ring A, and let S be a set of generators for a.An ideal maximal in the set of ideals generated by finite subsets of S must contain everyelement of S (otherwise it wouldn’t be maximal), and so equals a. 2

THEOREM 1.8 (KRULL INTERSECTION THEOREM). In every noetherian local ringAwithmaximal ideal m,

Tn�1m

n D f0g:

PROOF. Let a1; : : : ;ar generate m. Then mn consists of all finite sumsXi1C���CirDn

ci1���irai11 � � �a

irr ; ci1���ir 2 A:

In other words, mn consists of the elements of A that equal g.a1; : : : ;ar/ for some ho-mogeneous polynomial g.X1; : : : ;Xr/ 2 AŒX1; : : : ;Xr � of degree n. Let Sm be the set ofhomogeneous polynomials f of degree m such that f .a1; : : : ;ar/ 2

Tn�1m

n, and let abe the ideal in AŒX1; : : : ;Xr � generated by the set

SmSm. According to the lemma, there

exists a finite set ff1; : : : ;fsg of elements ofSmSm that generates a. Let di D degfi , and

let d D maxdi . Let b 2Tn�1m

n; then b 2 mdC1, and so b D f .a1; : : : ;ar/ for somehomogeneous polynomial f of degree d C1. By definition, f 2 SdC1 � a, and so

f D g1f1C�� �Cgsfs

for some gi 2AŒX1; : : : ;Xn�. As f and the fi are homogeneous, we can omit from each giall terms not of degree degf �degfi , since these terms cancel out. Thus, we may choose

16 1. PRELIMINARIES

the gi to be homogeneous of degree degf �degfi D dC1�di > 0. Then gi .a1; : : : ;ar/ 2m, and so

b D f .a1; : : : ;ar/DX

igi .a1; : : : ;ar/ �fi .a1; : : : ;ar/ 2m �

\n�1

mn:

Thus,T

mn Dm �T

mn, and Nakayama’s lemma implies thatT

mn D 0. 2

Unique factorization

Let A be an integral domain. An element a of A is irreducible if it is not zero, not a unit,and admits only trivial factorizations, i.e.,

aD bc H) b or c is a unit.

The element a is said to be prime if .a/ is a prime ideal, i.e.,

ajbc H) ajb or ajc.

An integral domain A is called a unique factorization domain if every nonzero nonunitin A can be written as a finite product of irreducible elements in exactly one way up to unitsand the order of the factors: In such a ring, an irreducible element a can divide a productbc only if it is an irreducible factor of b or c (write bc D aq and express b;c;q as productsof irreducible elements).

PROPOSITION 1.9. Let A be an integral domain, and let a be an element of A that isneither zero nor a unit. If a is prime, then a is irreducible, and the converse holds when Ais a unique factorization domain.

PROOF. Assume that a is prime. If a D bc then a divides bc, and so a divides b or c.Suppose the first, and write b D aq. Now a D bc D aqc, which implies that qc D 1, andthat c is a unit. Therefore a is irreducible.

For the converse, assume that a is irreducible. If ajbc, then (as we noted above) ajb orajc, and so a is prime. 2

PROPOSITION 1.10 (GAUSS’S LEMMA). Let A be a unique factorization domain withfield of fractions F . If f .X/ 2 AŒX� factors into the product of two nonconstant poly-nomials in F ŒX�, then it factors into the product of two nonconstant polynomials in AŒX�.

PROOF. Let f D gh in F ŒX�. For suitable c;d 2A, the polynomials g1D cg and h1D dhhave coefficients in A, and so we have a factorization

cdf D g1h1 in AŒX�.

If an irreducible element p of A divides cd , then, looking modulo .p/, we see that

0D g1 �h1 in .A=.p// ŒX�.

According to Proposition 1.9, .p/ is prime, and so .A=.p// ŒX� is an integral domain.Therefore, p divides all the coefficients of at least one of the polynomials g1;h1, say g1, sothat g1 D pg2 for some g2 2 AŒX�. Thus, we have a factorization

.cd=p/f D g2h1 in AŒX�.

Unique factorization 17

Continuing in this fashion, we can remove all the irreducible factors of cd , and so obtain afactorization of f in AŒX�. 2

Let A be a unique factorization domain. A nonzero polynomial

f D a0Ca1XC�� �CamXm

in AŒX� is said to be primitive if the coefficients ai have no common factor (other thanunits). Every polynomial f in AŒX� can be written f D c.f / � f1 with c.f / 2 A andf1 primitive. The element c.f /, well-defined up to multiplication by a unit, is called thecontent of f .

LEMMA 1.11. The product of two primitive polynomials is primitive.

PROOF. Let

f D a0Ca1XC�� �CamXm

g D b0Cb1XC�� �CbnXn;

be primitive polynomials, and let p be an irreducible element of A. Let ai0 be the firstcoefficient of f not divisible by p and bj0 the first coefficient of g not divisible by p. Thenall the terms in

PiCjDi0Cj0

aibj are divisible by p, except ai0bj0 , which is not divisibleby p. Therefore, p doesn’t divide the .i0C j0/th-coefficient of fg. We have shown thatno irreducible element of A divides all the coefficients of fg, which must therefore beprimitive. 2

LEMMA 1.12. For polynomials f;g 2 AŒX�,

c.fg/D c.f / � c.g/I

hence every factor in AŒX� of a primitive polynomial is primitive.

PROOF. Let f D c.f / �f1 and g D c.g/ �g1 with f1 and g1 primitive. Then

fg D c.f / � c.g/ �f1g1

with f1g1 primitive, and so c.fg/D c.f /c.g/. 2

PROPOSITION 1.13. If A is a unique factorization domain, then so also is AŒX�.

PROOF. From the factorization f D c.f /f1, we see that the irreducible elements of AŒX�are to be found among the constant polynomials and the primitive polynomials, but a con-stant polynomial is irreducible if and only if a is an irreducible element of A (obvious)and a primitive polynomial is irreducible if and only if it has no primitive factor of lowerdegree (by 1.12). From this it is clear that every nonzero nonunit f in AŒX� is a product ofirreducible elements.

From the factorization f D c.f /f1, we see that the irreducible elements of AŒX� areto be found among the constant polynomials and the primitive polynomials.

18 1. PRELIMINARIES

Letf D c1 � � �cmf1 � � �fn D d1 � � �drg1 � � �gs

be two factorizations of an element f of AŒX� into irreducible elements with the ci ;djconstants and the fi ;gj primitive polynomials. Then

c.f /D c1 � � �cm D d1 � � �dr (up to units in A),

and, on using that A is a unique factorization domain, we see that mD r and the ci ’s differfrom the di ’s only by units and ordering. Hence,

f1 � � �fn D g1 � � �gs (up to units in A).

Gauss’s lemma shows that the fi ;gj are irreducible polynomials in F ŒX� and, on usingthat F ŒX� is a unique factorization domain, we see that nD s and that the fi ’s differ fromthe gi ’s only by units in F and by their ordering. But if fi D a

bgj with a and b nonzero

elements of A, then bfi D agj . As fi and gj are primitive, this implies that b D a (up to aunit in A), and hence that a

bis a unit in A. 2

Polynomial rings

Let k be a field. A monomial in X1; : : : ;Xn is an expression of the form

Xa11 � � �X

ann ; aj 2 N:

The total degree of the monomial isPai . We sometimes denote the monomial by X˛;

˛ D .a1; : : : ;an/ 2 Nn.The elements of the polynomial ring kŒX1; : : : ;Xn� are finite sumsX

ca1���anXa11 � � �X

ann ; ca1���an 2 k; aj 2 N;

with the obvious notions of equality, addition, and multiplication. In particular, the mono-mials form a basis for kŒX1; : : : ;Xn� as a k-vector space.

The degree, deg.f /, of a nonzero polynomial f is the largest total degree of a mono-mial occurring in f with nonzero coefficient. Since deg.fg/D deg.f /Cdeg.g/, kŒX1; : : : ;Xn�is an integral domain and kŒX1; : : : ;Xn�� D k�. An element f of kŒX1; : : : ;Xn� is irre-ducible if it is nonconstant and f D gh H) g or h is constant.

THEOREM 1.14. The ring kŒX1; : : : ;Xn� is a unique factorization domain.

PROOF. Note that kŒX1; : : : ;Xn�1�ŒXn�D kŒX1; : : : ;Xn�; this simply says that every poly-nomial f in n variables X1; : : : ;Xn can be expressed uniquely as a polynomial in Xn withcoefficients in kŒX1; : : : ;Xn�1�,

f .X1; : : : ;Xn/D a0.X1; : : : ;Xn�1/XrnC�� �Car.X1; : : : ;Xn�1/:

Since k itself is a unique factorization domain (trivially), the theorem follows by inductionfrom Proposition 1.13. 2

COROLLARY 1.15. A nonzero proper principal ideal .f / in kŒX1; : : : ;Xn� is prime if andonly if f is irreducible.

PROOF. Special case of (1.9). 2

Integrality 19

Integrality

Let A be an integral domain, and let L be a field containing A. An element ˛ of L is saidto be integral over A if it is a root of a monic3 polynomial with coefficients in A, i.e., if itsatisfies an equation

˛nCa1˛n�1C : : :Can D 0; ai 2 A:

THEOREM 1.16. The set of elements of L integral over A forms a ring.

PROOF. Let ˛ and ˇ integral over A. Then there exists a monic polynomial

h.X/DXmC c1Xm�1C�� �C cm; ci 2 A;

having ˛ and ˇ among its roots (e.g., take h to be the product of the polynomials exhibitingthe integrality of ˛ and ˇ). Write

h.X/D

mYiD1

.X � i /

with the i in an algebraic closure of L. Up to sign, the ci are the elementary symmetricpolynomials in the i (cf. FT p. 74). I claim that every symmetric polynomial in the iwith coefficients in A lies in A: let p1;p2; : : : be the elementary symmetric polynomials inX1; : : : ;Xm; if P 2 AŒX1; : : : ;Xm� is symmetric, then the symmetric polynomials theorem(ibid. 5.33) shows that P.X1; : : : ;Xm/DQ.p1; : : : ;pm/ for someQ 2AŒX1; : : : ;Xm�, andso

P. 1; : : : ; m/DQ.�c1; c2; : : :/ 2 A.

The coefficients of the polynomialsY1�i;j�m

.X � i j / andY

1�i;j�m

.X � . i ˙ j //

are symmetric polynomials in the i with coefficients in A, and therefore lie in A. As thepolynomials are monic and have ˛ˇ and ˛˙ˇ among their roots, this shows that theseelements are integral. 2

For a less computational proof, see CA 5.3.

DEFINITION 1.17. The ring of elements of L integral over A is called the integral closureof A in L.

PROPOSITION 1.18. Let A be an integral domain with field of fractions F , and let L be afield containing F . If ˛ 2 L is algebraic over F , then there exists a d 2 A such that d˛ isintegral over A.

PROOF. By assumption, ˛ satisfies an equation

˛mCa1˛m�1C�� �Cam D 0; ai 2 F:

3A polynomial is monic if its leading coefficient is 1, i.e., f .X/DXnC terms of degree < n.

20 1. PRELIMINARIES

Let d be a common denominator for the ai , so that dai 2A, all i , and multiply through theequation by dm:

dm˛mCa1dm˛m�1C�� �Camd

mD 0:

We can rewrite this as

.d˛/mCa1d.d˛/m�1C�� �Camd

mD 0:

As a1d; : : : ;amdm 2 A, this shows that d˛ is integral over A. 2

COROLLARY 1.19. Let A be an integral domain and let L be an algebraic extension of thefield of fractions of A. Then L is the field of fractions of the integral closure of A in L.

PROOF. The proposition shows that every ˛ 2 L can be written ˛ D ˇ=d with ˇ integralover A and d 2 A. 2

DEFINITION 1.20. An integral domain A is integrally closed if it is equal to its integralclosure in its field of fractions F , i.e., if

˛ 2 F; ˛ integral over A H) ˛ 2 A:

PROPOSITION 1.21. Every unique factorization domain (e.g. a principal ideal domain) isintegrally closed.

PROOF. Let a=b, a;b 2 A, be integral over A. If a=b … A, then there is an irreducibleelement p of A dividing b but not a. As a=b is integral over A, it satisfies an equation

.a=b/nCa1.a=b/n�1C�� �Can D 0, ai 2 A:

On multiplying through by bn, we obtain the equation

anCa1an�1bC�� �Canb

nD 0:

The element p then divides every term on the left except an, and hence must divide an.Since it doesn’t divide a, this is a contradiction. 2

PROPOSITION 1.22. Let A be an integrally closed integral domain, and let L be a finiteextension of the field of fractions F of A. An element ˛ of L is integral over A if and onlyif its minimum polynomial over F has coefficients in A.

PROOF. Let ˛ be integral over A, so that

˛mCa1˛m�1C�� �Cam D 0; some ai 2 A:

Let ˛0 be a conjugate of ˛, i.e., a root of the minimum polynomial f .X/ of ˛ over F . Thenthere is an F -isomorphism4

� WF Œ˛�! F Œ˛0�; �.˛/D ˛0

4Recall (FT �1) that the homomorphism X 7! ˛WF ŒX�! F Œ˛� defines an isomorphism F ŒX�=.f /!

F Œ˛�, where f is the minimum polynomial of ˛.

Direct limits (summary) 21

On applying � to the above equation we obtain the equation

˛0mCa1˛0m�1

C�� �Cam D 0;

which shows that ˛0 is integral over A. Hence all the conjugates of ˛ are integral over A,and it follows from (1.16) that the coefficients of f .X/ are integral over A. They lie inF , and A is integrally closed, and so they lie in A. This proves the “only if” part of thestatement, and the “if” part is obvious. 2

COROLLARY 1.23. LetA be an integrally closed integral domain with field of fractions F ,and let f .X/ be a monic polynomial in AŒX�. Then every monic factor of f .X/ in F ŒX�has coefficients in A.

PROOF. It suffices to prove this for an irreducible monic factor g of f in F ŒX�. Let ˛ be aroot of g in some extension field of F . Then g is the minimum polynomial ˛, which, beingalso a root of f , is integral. Therefore g has coefficients in A. 2

Direct limits (summary)

DEFINITION 1.24. A partial ordering� on a set I is said to be directed, and the pair .I;�/is called a directed set, if for all i;j 2 I there exists a k 2 I such that i;j � k.

DEFINITION 1.25. Let .I;�/ be a directed set, and let R be a ring.

(a) An direct system of R-modules indexed by .I;�/ is a family .Mi /i2I of R-modulestogether with a family .˛ij WMi !Mj /i�j of R-linear maps such that ˛ii D idMi and

˛j

kı˛ij D ˛

ik

all i � j � k.(b) An R-module M together with a family .˛i WMi !M/i2I of R-linear maps satisfy-

ing ˛i D ˛j ı˛ij all i � j is said to be a direct limit of the system in (a) if it has thefollowing universal property: for any other R-module N and family .ˇi WMi ! N/

of R-linear maps such that ˇi D ˇj ı˛ij all i � j , there exists a unique morphism˛WM !N such that ˛ ı˛i D ˇi for i .

Clearly, the direct limit (if it exists), is uniquely determined by this condition up to a uniqueisomorphism. We denote it lim

�!.Mi ;˛

ji /, or just lim

�!Mi .

Criterion

An R-module M together with R-linear maps ˛i WMi !M is the direct limit of a system.Mi ;˛

ji / if and only if

(a) M DSi2I ˛

i .Mi /, and(b) mi 2Mi maps to zero in M if and only if it maps to zero in Mj for some j � i .

22 1. PRELIMINARIES

Construction

LetM D

Mi2I

Mi=M0

where M 0 is the R-submodule generated by the elements

mi �˛ij .mi / all i < j , mi 2Mi :

Let ˛i .mi /D mi CM 0. Then certainly ˛i D ˛j ı˛ij for all i � j . For any R-module Nand R-linear maps ˇj WMj !N , there is a unique mapM

i2I

Mi !N;

namely,Pmi 7!

Pˇi .mi /, sending mi to ˇi .mi /, and this map factors through M and is

the unique R-linear map with the required properties.Direct limits of R-algebras, etc., are defined similarly.

Rings of fractions

A multiplicative subset of a ring A is a subset S with the property:

1 2 S; a;b 2 S H) ab 2 S:

Define an equivalence relation on A�S by

.a;s/� .b; t/ ” u.at �bs/D 0 for some u 2 S:

Write as

for the equivalence class containing .a;s/, and define addition and multiplicationof equivalence classes in the way suggested by the notation:

asCbtD

atCbsst

; asbtD

abst:

It is easy to check that these do not depend on the choices of representatives for the equiv-alence classes, and that we obtain in this way a ring

S�1ADnasj a 2 A; s 2 S

oand a ring homomorphism a 7! a

1WA! S�1A, whose kernel is

fa 2 A j saD 0 for some s 2 Sg:

For example, if A is an integral domain an 0 … S , then a 7! a1

is injective, but if 0 2 S , thenS�1A is the zero ring.

Write i for the homomorphism a 7! a1WA! S�1A.

PROPOSITION 1.26. The pair .S�1A;i/ has the following universal property: every ele-ment s 2S maps to a unit in S�1A, and any other homomorphismA!B with this propertyfactors uniquely through i :

A S�1A

B:

i

9Š

Rings of fractions 23

PROOF. If ˇ exists,

s asD a H) ˇ.s/ˇ.a

s/D ˇ.a/ H) ˇ.a

s/D ˛.a/˛.s/�1;

and so ˇ is unique. Defineˇ.as/D ˛.a/˛.s/�1:

Then

acD

bdH) s.ad �bc/D 0 some s 2 S H) ˛.a/˛.d/�˛.b/˛.c/D 0

because ˛.s/ is a unit in B , and so ˇ is well-defined. It is obviously a homomorphism. 2

As usual, this universal property determines the pair .S�1A;i/ uniquely up to a uniqueisomorphism.

When A is an integral domain and S D Ar f0g, F D S�1A is the field of fractions ofA. In this case, for any other multiplicative subset T of A not containing 0, the ring T �1Acan be identified with the subring fa

t2 F j a 2 A, t 2 Sg of F .

We shall be especially interested in the following examples.

EXAMPLE 1.27. Let h 2 A. Then Sh D f1;h;h2; : : :g is a multiplicative subset of A, andwe let AhD S�1h A. Thus every element of Ah can be written in the form a=hm, a 2A, and

ahmD

bhn” hN .ahn�bhm/D 0; some N:

If h is nilpotent, then Ah D 0, and if A is an integral domain with field of fractions F andh¤ 0, then Ah is the subring of F of elements of the form a=hm, a 2 A, m 2 N:

EXAMPLE 1.28. Let p be a prime ideal in A. Then Sp D Ar p is a multiplicative subsetof A, and we let Ap D S

�1p A. Thus each element of Ap can be written in the form a

c, c … p,

andacD

bd” s.ad �bc/D 0, some s … p:

The subset mD fasj a 2 p; s … pg is a maximal ideal in Ap, and it is the only maximal ideal,

i.e., Ap is a local ring.5 When A is an integral domain with field of fractions F , Ap is thesubring of F consisting of elements expressible in the form a

s, a 2 A, s … p.

LEMMA 1.29. (a) For every ring A and h 2 A, the mapPaiX

i 7!P ai

hidefines an iso-

morphismAŒX�=.1�hX/

'�! Ah:

(b) For every multiplicative subset S of A, S�1A ' lim�!

Ah, where h runs over theelements of S (partially ordered by division).

5First check m is an ideal. Next, if m D Ap, then 1 2 m; but if 1 D as for some a 2 p and s … p, then

u.s�a/D 0 some u … p, and so ua D us … p, which contradicts a 2 p. Finally, m is maximal because everyelement of Ap not in m is a unit.

24 1. PRELIMINARIES

PROOF. (a) If hD 0, both rings are zero, and so we may assume h¤ 0. In the ring AŒx�DAŒX�=.1�hX/, 1 D hx, and so h is a unit. Let ˛WA! B be a homomorphism of ringssuch that ˛.h/ is a unit in B . The homomorphism

PaiX

i 7!P˛.ai /˛.h/

�i WAŒX�! B

factors through AŒx� because 1�hX 7! 1�˛.h/˛.h/�1D 0, and, because ˛.h/ is a unit inB , this is the unique extension of ˛ to AŒx�. Therefore AŒx� has the same universal propertyas Ah, and so the two are (uniquely) isomorphic by an isomorphism that fixes elements ofA and makes h�1 correspond to x.

(b) When hjh0, say, h0 D hg, there is a canonical homomorphism ah7!

agh0WAh! Ah0 ,

and so the rings Ah form a direct system indexed by the set S . When h 2 S , the homomor-phism A! S�1A extends uniquely to a homomorphism a

h7!

ahWAh! S�1A (1.26), and

these homomorphisms are compatible with the maps in the direct system. Now apply thecriterion p21 to see that S�1A is the direct limit of the Ah. 2

Let S be a multiplicative subset of a ring A, and let S�1A be the corresponding ring offractions. Any ideal a in A, generates an ideal S�1a in S�1A. If a contains an element ofS , then S�1a contains a unit, and so is the whole ring. Thus some of the ideal structure ofA is lost in the passage to S�1A, but, as the next lemma shows, some is retained.

PROPOSITION 1.30. Let S be a multiplicative subset of the ring A. The map

p 7! S�1pD .S�1A/p

is a bijection from the set of prime ideals of A disjoint from S to the set of prime ideals ofS�1A with inverse q 7!(inverse image of q in A).

PROOF. For an ideal b of S�1A, let bc be the inverse image of b in A, and for an ideal a ofA, let ae D .S�1A/a be the ideal in S�1A generated by the image of a.

For an ideal b of S�1A, certainly, b � bce. Conversely, if as2 b, a 2 A, s 2 S , then

a12 b, and so a 2 bc . Thus a

s2 bce, and so bD bce.

For an ideal a ofA, certainly a� aec . Conversely, if a 2 aec , then a12 ae, and so a

1Da0

s

for some a0 2 a, s 2 S . Thus, t .as�a0/D 0 for some t 2 S , and so ast 2 a. If a is a primeideal disjoint from S , this implies that a 2 a: for such an ideal, aD aec .

If b is prime, then certainly bc is prime. For any ideal a of A, S�1A=ae ' NS�1.A=a/where NS is the image of S in A=a. If a is a prime ideal disjoint from S , then NS�1.A=a/ isa subring of the field of fractions of A=a, and is therefore an integral domain. Thus, ae isprime.

We have shown that p 7! pe and q 7! qc are inverse bijections between the prime idealsof A disjoint from S and the prime ideals of S�1A. 2

LEMMA 1.31. Let m be a maximal ideal of a noetherian integral domain A, and let n DmAm. For all n, the map

aCmn 7! aCnnWA=mn! Am=nn

is an isomorphism. Moreover, it induces isomorphisms

mr=mn! nr=nn

for all r < n.

Tensor Products 25

PROOF. The second statement follows from the first, because of the exact commutativediagram .r < n/:

0 ����! mr=mn ����! A=mn ����! A=mr ����! 0??y ??y' ??y'0 ����! nr=nn ����! Am=n

n ����! Am=nr ����! 0:

Let S D Arm, so that Am D S�1A. Because S contains no zero divisors, the map

a 7! a1WA! Am is injective, and I’ll identify A with its image. In order to show that the

map A=mn!An=nn is injective, we have to show that nm\ADmm. But nm DmnAm D

S�1mm, and so we have to show that mm D .S�1mm/\A. An element of .S�1mm/\Acan be written a D b=s with b 2 mm, s 2 S , and a 2 A. Then sa 2 mm, and so sa D 0 inA=mm. The only maximal ideal containing mm is m (because m0 �mm H) m0 �m/, andso the only maximal ideal in A=mm is m=mm. As s is not in m=mm, it must be a unit inA=mm, and as saD 0 in A=mm, a must be 0 in A=mm, i.e., a 2mm:

We now prove that the map is surjective. Let as2 Am, a 2 A, s 2 Arm. The only

maximal ideal of A containing mm is m, and so no maximal ideal contains both s and mm;it follows that .s/CmmDA. Therefore, there exist b 2A and q 2mm such that sbCqD 1.Because s is invertible in Am=n

m, as

is the unique element of this ring such that s asD a;

since s.ba/D a.1�q/, the image of ba in Am also has this property and therefore equalsas

. 2

PROPOSITION 1.32. In every noetherian ring, only 0 lies in all powers of all maximalideals.

PROOF. Let a be an element of a noetherian ring A. If a¤ 0, then fb j baD 0g is a properideal, and so is contained in some maximal ideal m. Then a

1is nonzero in Am, and so

a1… .mAm/

n for some n (by the Krull intersection theorem), which implies that a …mn. 2

NOTES. For more on rings of fractions, see CA �6. In particular, 1.31 holds for all noetherian rings(CA 6.7).

Tensor Products

Tensor products of modules

Let R be a ring. A map �WM �N ! P of R-modules is said to be R-bilinear if

�.xCx0;y/D �.x;y/C�.x0;y/; x;x0 2M; y 2N

�.x;yCy0/D �.x;y/C�.x;y0/; x 2M; y;y0 2N

�.rx;y/D r�.x;y/; r 2R; x 2M; y 2N

�.x;ry/D r�.x;y/; r 2R; x 2M; y 2N;

i.e., if � is R-linear in each variable. An R-module T together with an R-bilinear map�WM �N ! T is called the tensor product of M and N over R if it has the following

26 1. PRELIMINARIES

universal property: every R-bilinear map �0WM �N ! T 0 factors uniquely through �,

M �N T

T 0:

�

�0 9Š

As usual, the universal property determines the tensor product uniquely up to a uniqueisomorphism. We write it M ˝RN .

Construction Let M and N be R-modules, and let R.M�N/ be the free R-module withbasis M �N . Thus each element R.M�N/ can be expressed uniquely as a finite sumX

ri .xi ;yi /; ri 2R; xi 2M; yi 2N:

Let K be the submodule of R.M�N/ generated by the following elements

.xCx0;y/� .x;y/� .x0;y/; x;x0 2M; y 2N

.x;yCy0/� .x;y/� .x;y0/; x 2M; y;y0 2N

.rx;y/� r.x;y/; r 2R; x 2M; y 2N

.x;ry/� r.x;y/; r 2R; x 2M; y 2N;

and defineM ˝RN DR

.M�N/=K:

Write x˝y for the class of .x;y/ in M ˝RN . Then

.x;y/ 7! x˝yWM �N !M ˝RN

is R-bilinear — we have imposed the fewest relations necessary to ensure this. Everyelement of M ˝RN can be written as a finite sumX

ri .xi ˝yi /; ri 2R; xi 2M; yi 2N;

and all relations among these symbols are generated by the following

.xCx0/˝y D x˝yCx0˝y

x˝ .yCy0/D x˝yCx˝y0

r.x˝y/D .rx/˝y D x˝ ry:

The pair .M ˝RN;.x;y/ 7! x˝y/ has the following universal property:

Tensor products of algebras

Let A and B be k-algebras. A k-algebra C together with homomorphisms i WA! C andj WB!C is called the tensor product ofA andB if it has the following universal property:

Tensor Products 27

for every pair of homomorphisms (of k-algebras) ˛WA!R and ˇWB!R, there is a uniquehomomorphism WC !R such that ı i D ˛ and ıj D ˇ:

A C B

R:

i j

˛ ˇ9Š

If it exists, the tensor product, is uniquely determined up to a unique isomorphism by thisproperty. We write it A˝k B .

Construction Regard A and B as k-vector spaces, and form the tensor product A˝k B .There is a multiplication map A˝k B �A˝k B! A˝k B for which

.a˝b/.a0˝b0/D aa0˝bb0.

This makes A˝k B into a ring, and the homomorphism

c 7! c.1˝1/D c˝1D 1˝ c

makes it into a k-algebra. The maps

a 7! a˝1WA! C and b 7! 1˝bWB! C

are homomorphisms, and they makeA˝kB into the tensor product ofA andB in the abovesense.

EXAMPLE 1.33. The algebra B , together with the given map k! B and the identity mapB ! B , has the universal property characterizing k˝k B . In terms of the constructivedefinition of tensor products, the map c˝b 7! cbWk˝k B! B is an isomorphism.

EXAMPLE 1.34. The ring kŒX1; : : : ;Xm;XmC1; : : : ;XmCn�, together with the obvious in-clusions

kŒX1; : : : ;Xm� ,! kŒX1; : : : ;XmCn� - kŒXmC1; : : : ;XmCn�

is the tensor product of kŒX1; : : : ;Xm� and kŒXmC1; : : : ;XmCn�. To verify this we only haveto check that, for every k-algebra R, the map

Homk-alg.kŒX1; : : : ;XmCn�;R/! Homk-alg.kŒX1; : : :�;R/�Homk-alg.kŒXmC1; : : :�;R/

induced by the inclusions is a bijection. But this map can be identified with the bijection

RmCn!Rm�Rn:

In terms of the constructive definition of tensor products, the map

f ˝g 7! fgWkŒX1; : : : ;Xm�˝k kŒXmC1; : : : ;XmCn�! kŒX1; : : : ;XmCn�

is an isomorphism.

28 1. PRELIMINARIES

REMARK 1.35. (a) If .b˛/ is a family of generators (resp. basis) for B as a k-vector space,then .1˝b˛/ is a family of generators (resp. basis) for A˝k B as an A-module.

(b) Let k ,!˝ be fields. Then

˝˝k kŒX1; : : : ;Xn�'˝Œ1˝X1; : : : ;1˝Xn�'˝ŒX1; : : : ;Xn�:

If AD kŒX1; : : : ;Xn�=.g1; : : : ;gm/, then

˝˝k A'˝ŒX1; : : : ;Xn�=.g1; : : : ;gm/:

(c) If A and B are algebras of k-valued functions on sets S and T respectively, then.f ˝g/.x;y/D f .x/g.y/ realizes A˝k B as an algebra of k-valued functions on S �T .

For more details on tensor products, see CA �8.

Extension of scalars

Let R be a commutative ring and A an R-algebra (not necessarily commutative) such thatthe image of R! A lies in the centre of A. Then we have a functor M 7! A˝RM fromleft R-modules to left A-modules.

Behaviour with respect to direct limits

PROPOSITION 1.36. Direct limits commute with tensor products:

lim�!i2I

Mi ˝R lim�!j2J

Nj ' lim�!

.i;j /2I�J

.Mi ˝RNj /:

PROOF. Using the universal properties of direct limits and tensor products, one sees easilythat lim�!.Mi ˝R Nj / has the universal property to be the tensor product of lim

�!Mi and

lim�!

Nj . 2

Flatness

For every R-module M , the functor N 7!M ˝RN is right exact, i.e.,

M ˝RN0!M ˝RN !M ˝RN

00! 0

is exact wheneverN 0!N !N 00! 0

is exact. If M ˝RN !M ˝RN0 is injective whenever N ! N 0 is injective, then M is

said to be flat. Thus M is flat if and only if the functor N 7!M ˝RN is exact. Similarly,an R-algebra A is flat if N 7! A˝RN is flat.

Categories and functors

A category C consists of

(a) a class of objects ob.C/;

Categories and functors 29

(b) for each pair .a;b/ of objects, a set Mor.a;b/, whose elements are called morphismsfrom a to b, and are written ˛Wa! b;

(c) for each triple of objects .a;b;c/ a map (called composition)

.˛;ˇ/ 7! ˇ ı˛WMor.a;b/�Mor.b;c/!Mor.a;c/:

Composition is required to be associative, i.e., . ıˇ/ı˛ D ı .ˇ ı˛/, and for each objecta there is required to be an element ida 2Mor.a;a/ such that ida ı˛ D ˛, ˇ ı ida D ˇ, forall ˛ and ˇ for which these composites are defined. The sets Mor.a;b/ are required to bedisjoint (so that a morphism ˛ determines its source and target).

EXAMPLE 1.37. (a) There is a category of sets, Sets, whose objects are the sets and whosemorphisms are the usual maps of sets.

(b) There is a category Affk of affine k-algebras, whose objects are the affine k-algebrasand whose morphisms are the homomorphisms of k-algebras.

(c) In Chapter 4 below, we define a category Vark of algebraic varieties over k, whoseobjects are the algebraic varieties over k and whose morphisms are the regular maps.

The objects in a category need not be sets with structure, and the morphisms need notbe maps.

Let C and D be categories. A covariant functor F from C to D consists of

(a) a map a 7! F.a/ sending each object of C to an object of D, and,(b) for each pair of objects a;b of C, a map

˛ 7! F.˛/WMor.a;b/!Mor.F.a/;F.b//

such that F.idA/D idF.A/ and F.ˇ ı˛/D F.ˇ/ıF.˛/.

A contravariant functor is defined similarly, except that the map on morphisms is

˛ 7! F.˛/WMor.a;b/!Mor.F.b/;F.a//

A functor F WC! D is full (resp. faithful, fully faithful) if, for all objects a and b ofC, the map

Mor.a;b/!Mor.F.a/;F.b//

is a surjective (resp. injective, bijective).A covariant functor F WA! B of categories is said to be an equivalence of categories

if it is fully faithful and every object of B is isomorphic to an object of the form F.a/,a 2 ob.A/ (F is essentially surjective). One can show that such a functor F has a quasi-inverse, i.e., that there is a functor GWB! A, which is also an equivalence, and for whichthere exist natural isomorphisms G.F.a//� a and F.G.b//� b.6

6For each object b of B, choose an objectG.b/ of A and an isomorphism F.G.b//! b. For each morphismˇWb! b0 in B, let G.ˇ/ be the unique morphism such that

F.G.b// �����! b??yF.ˇ/ ??yˇF.G.b0// �����! b0

commutes. Then G is a quasi-inverse to F .

30 1. PRELIMINARIES

Similarly one defines the notion of a contravariant functor being an equivalence of cat-egories.

Any fully faithful functor F WC! D defines an equivalence of C with the full subcat-egory of D whose objects are isomorphic to F.a/ for some object a of C. The essentialimage of a fully faithful functor F WC! D consists of the objects of D isomorphic to anobject of the form F.a/, a 2 ob.C/:

Let F andG be two functors C!D. A morphism (or natural transformation) ˛WF !G is a collection of morphisms ˛.a/WF.a/! G.a/, one for each object a of C, such that,for every morphism uWa! b in C, the following diagram commutes:

a??yub

F.a/˛.a/����! G.a/??yF.u/ ??yG.u/

F.b/˛.b/����! G.b/:

(**)

With this notion of morphism, the functors C! D form a category Fun.C;D/ (providedthat we ignore the problem that Mor.F;G/ may not be a set, but only a class).

For any object V of a category C, we have a contravariant functor

hV WC! Set

that sends an object a to the set Mor.a;V / and sends a morphism ˛Wa! b to the map

' 7! ' ı˛WhV .b/! hV .a/;

i.e., hV .�/ D Mor.�;V / and hV .˛/ D �ı ˛. Let ˛WV ! W be a morphism in C. Thecollection of maps

h˛.a/WhV .a/! hW .a/; ' 7! ˛ ı'

is a morphism of functors.

PROPOSITION 1.38 (YONEDA LEMMA). For any contravariant functor F WC! Set,

Mor.hV ;F /' F.V /:

In particular, when F D hW ,

Mor.hV ;hW /'Mor.V;W /

— to give a natural transformation hV ! hW is the same as to give a morphism V !W .

PROOF. An element x of F.V / defines a natural transformation hV ! F , namely,

˛ 7! F.˛/.x/WhV .T /! F.T /; ˛ 2 hV .T /D Hom.T;V /:

Conversely, a natural transformation hV ! F defines an element of F.V /, namely, theimage of the “universal” element idV under hV .V /! F.V /. It is easy to check that thesetwo maps are inverse and are natural in both F and V . 2

Algorithms for polynomials 31

Algorithms for polynomialsAs an introduction to algorithmic algebraic geometry, we derive some algorithms for working withpolynomial rings. This section is little more than a summary of the first two chapters of Cox etal.1992 to which I refer the reader for more details. Those not interested in algorithms can skip theremainder of this chapter. Throughout, k is a field (not necessarily algebraically closed).

The two main results will be:

(a) An algorithmic proof of the Hilbert basis theorem: every ideal in kŒX1; : : : ;Xn� has a finiteset of generators (in fact, of a special kind).

(b) There exists an algorithm for deciding whether a polynomial belongs to an ideal.

Division in kŒX�

The division algorithm allows us to divide a nonzero polynomial into another: let f and g bepolynomials in kŒX� with g ¤ 0; then there exist unique polynomials q;r 2 kŒX� such that f DqgC r with either r D 0 or degr < degg. Moreover, there is an algorithm for deciding whetherf 2 .g/, namely, find r and check whether it is zero.

In Maple,quo.f;g;X/I computes qrem.f;g;X/I computes r

Moreover, the Euclidean algorithm allows you to pass from a finite set of generators for an idealin kŒX� to a single generator by successively replacing each pair of generators with their greatestcommon divisor.

Orderings on monomials

Before we can describe an algorithm for dividing in kŒX1; : : : ;Xn�, we shall need to choose a wayof ordering monomials. Essentially this amounts to defining an ordering on Nn. There are two mainsystems, the first of which is preferred by humans, and the second by machines.

(Pure) lexicographic ordering (lex). Here monomials are ordered by lexicographic (dictionary)order. More precisely, let ˛ D .a1; : : : ;an/ and ˇ D .b1; : : : ;bn/ be two elements of Nn; then

˛ > ˇ and X˛ >Xˇ (lexicographic ordering)

if, in the vector difference ˛�ˇ (an element of Zn), the left-most nonzero entry is positive. Forexample,

XY 2 > Y 3Z4I X3Y 2Z4 >X3Y 2Z:

Note that this isn’t quite how the dictionary would order them: it would put XXXYYZZZZ afterXXXYYZ.

Graded reverse lexicographic order (grevlex). Here monomials are ordered by total degree,with ties broken by reverse lexicographic ordering. Thus, ˛ > ˇ if

Pai >

Pbi , or

Pai D

Pbi

and in ˛�ˇ the right-most nonzero entry is negative. For example:

X4Y 4Z7 >X5Y 5Z4 (total degree greater)

XY 5Z2 >X4YZ3; X5YZ > X4YZ2:

Orderings on kŒX1; : : : ;Xn�

Fix an ordering on the monomials in kŒX1; : : : ;Xn�. Then we can write an element f of kŒX1; : : : ;Xn�in a canonical fashion by re-ordering its elements in decreasing order. For example, we would write

f D 4XY 2ZC4Z2�5X3C7X2Z2

32 1. PRELIMINARIES

asf D�5X3C7X2Z2C4XY 2ZC4Z2 (lex)

orf D 4XY 2ZC7X2Z2�5X3C4Z2 (grevlex)

Let f DPa˛X

˛ 2 kŒX1; : : : ;Xn�. Write it in decreasing order:

f D a˛0X˛0Ca˛1X

˛1C�� � ; ˛0 > ˛1 > � � � ; a˛0 ¤ 0:

Then we define:

(a) the multidegree of f to be multdeg.f /D ˛0;

(b) the leading coefficient of f to be LC.f /D a˛0 ;

(c) the leading monomial of f to be LM.f /DX˛0 ;

(d) the leading term of f to be LT.f /D a˛0X˛0 .

For example, for the polynomial f D 4XY 2ZC�� � , the multidegree is .1;2;1/, the leading coeffi-cient is 4, the leading monomial is XY 2Z, and the leading term is 4XY 2Z.

The division algorithm in kŒX1; : : : ;Xn�

Fix a monomial ordering in Nn. Suppose given a polynomial f and an ordered set .g1; : : : ;gs/ ofpolynomials; the division algorithm then constructs polynomials a1; : : : ;as and r such that

f D a1g1C�� �CasgsC r

where either r D 0 or no monomial in r is divisible by any of LT.g1/; : : : ;LT.gs/.STEP 1: If LT.g1/jLT.f /, divide g1 into f to get

f D a1g1Ch; a1 DLT.f /LT.g1/

2 kŒX1; : : : ;Xn�:

If LT.g1/jLT.h/, repeat the process until

f D a1g1Cf1

(different a1) with LT.f1/ not divisible by LT.g1/. Now divide g2 into f1, and so on, until

f D a1g1C�� �CasgsC r1

with LT.r1/ not divisible by any of LT.g1/; : : : ;LT.gs/.STEP 2: Rewrite r1 D LT.r1/C r2, and repeat Step 1 with r2 for f :

f D a1g1C�� �CasgsCLT.r1/C r3

(different ai ’s).STEP 3: Rewrite r3 D LT.r3/C r4, and repeat Step 1 with r4 for f :

f D a1g1C�� �CasgsCLT.r1/CLT.r3/C r3

(different ai ’s).Continue until you achieve a remainder with the required property. In more detail,7 after di-

viding through once by g1; : : : ;gs , you repeat the process until no leading term of one of the gi ’sdivides the leading term of the remainder. Then you discard the leading term of the remainder, andrepeat.

7This differs from the algorithm in Cox et al. 1992, p63, which says to go back to g1 after every successfuldivision.

Algorithms for polynomials 33

EXAMPLE 1.39. (a) Consider

f DX2Y CXY 2CY 2; g1 DXY �1; g2 D Y2�1:

First, on dividing g1 into f , we obtain

X2Y CXY 2CY 2 D .XCY /.XY �1/CXCY 2CY:

This completes the first step, because the leading term of Y 2�1 does not divide the leading term ofthe remainder XCY 2CY . We discard X , and write

Y 2CY D 1 � .Y 2�1/CY C1:

Altogether

X2Y CXY 2CY 2 D .XCY / � .XY �1/C1 � .Y 2�1/CXCY C1:

(b) Consider the same polynomials, but with a different order for the divisors

f DX2Y CXY 2CY 2; g1 D Y2�1; g2 DXY �1:

In the first step,

X2Y CXY 2CY 2 D .XC1/ � .Y 2�1/CX � .XY �1/C2XC1:

Thus, in this case, the remainder is 2XC1.

REMARK 1.40. If r D 0, then f 2 .g1; : : : ;gs/, but, because the remainder depends on the orderingof the gi , the converse is false. For example, (lex ordering)

XY 2�X D Y � .XY C1/C0 � .Y 2�1/C�X �Y

butXY 2�X DX � .Y 2�1/C0 � .XY C1/C0:

Thus, the division algorithm (as stated) will not provide a test for f lying in the ideal generated byg1; : : : ;gs .

Monomial ideals

In general, an ideal a can contain a polynomial without containing the individual monomials of thepolynomial; for example, the ideal aD .Y 2�X3/ contains Y 2�X3 but not Y 2 or X3.

DEFINITION 1.41. An ideal a is monomial ifXc˛X

˛2 a and c˛ ¤ 0 H) X˛ 2 a:

PROPOSITION 1.42. Let a be a monomial ideal, and let A D f˛ j X˛ 2 ag. Then A satisfies thecondition

˛ 2 A; ˇ 2 Nn H) ˛Cˇ 2 A (*)

and a is the k-subspace of kŒX1; : : : ;Xn� generated by the X˛ , ˛ 2A. Conversely, if A is a subset ofNn satisfying (*), then the k-subspace a of kŒX1; : : : ;Xn� generated by fX˛ j ˛ 2 Ag is a monomialideal.

34 1. PRELIMINARIES

PROOF. It is clear from its definition that a monomial ideal a is the k-subspace of kŒX1; : : : ;Xn�generated by the set of monomials it contains. If X˛ 2 a and Xˇ 2 kŒX1; : : : ;Xn�, then X˛Xˇ DX˛Cˇ 2 a, and so A satisfies the condition (*). Conversely, X

˛2A

c˛X˛

!0@Xˇ2Nn

dˇXˇ

1ADX˛;ˇ

c˛dˇX˛Cˇ (finite sums);

and so if A satisfies (*), then the subspace generated by the monomials X˛ , ˛ 2 A, is an ideal. 2

The proposition gives a classification of the monomial ideals in kŒX1; : : : ;Xn�: they are in one-to-one correspondence with the subsets A of Nn satisfying (*). For example, the monomial ideals inkŒX� are exactly the ideals .Xn/, n � 0, and the zero ideal (corresponding to the empty set A). Wewrite

hX˛ j ˛ 2 Ai

for the ideal corresponding to A (subspace generated by the X˛ , ˛ 2 A).

LEMMA 1.43. Let S be a subset ofNn. Then the ideal a generated by fX˛ j ˛ 2 Sg is the monomialideal corresponding to

AdefD fˇ 2 Nn j ˇ�˛ 2 S; some ˛ 2 Sg:

In other words, a monomial is in a if and only if it is divisible by one of the X˛ , ˛ 2 S .

PROOF. Clearly A satisfies (*), and a � hXˇ j ˇ 2 Ai. Conversely, if ˇ 2 A, then ˇ�˛ 2 Nn forsome ˛ 2 S , and Xˇ D X˛Xˇ�˛ 2 a. The last statement follows from the fact that X˛jXˇ ”ˇ�˛ 2 Nn. 2

Let A� N2 satisfy (*). From the geometry of A, it is clear that there is a finite set of elementsS D f˛1; : : : ;˛sg of A such that

AD fˇ 2 N2 j ˇ�˛i 2 N2; some ˛i 2 Sg:

(The ˛i ’s are the “corners” of A.) Moreover, the ideal hX˛ j ˛ 2 Ai is generated by the monomialsX˛i , ˛i 2 S . This suggests the following result.

THEOREM 1.44 (DICKSON’S LEMMA). Let a be the monomial ideal corresponding to the subsetA� Nn. Then a is generated by a finite subset of fX˛ j ˛ 2 Ag.

PROOF. This is proved by induction on the number of variables — Cox et al. 1992, p70. 2

Hilbert Basis Theorem

DEFINITION 1.45. For a nonzero ideal a in kŒX1; : : : ;Xn�, we let .LT.a// be the ideal generated byfLT.f / j f 2 ag:

LEMMA 1.46. Let a be a nonzero ideal in kŒX1; : : : ;Xn�; then .LT.a// is a monomial ideal, and itequals .LT.g1/; : : : ;LT.gn// for some g1; : : : ;gn 2 a.

PROOF. Since .LT.a// can also be described as the ideal generated by the leading monomials (ratherthan the leading terms) of elements of a, it follows from Lemma 1.43 that it is monomial. NowDickson’s Lemma shows that it equals .LT.g1/; : : : ;LT.gs// for some gi 2 a. 2

THEOREM 1.47 (HILBERT BASIS THEOREM). Every ideal a in kŒX1; : : : ;Xn� is finitely gener-ated; in fact, a is generated by any elements of a whose leading terms generate LT.a/.

Algorithms for polynomials 35

PROOF. Let g1; : : : ;gn be as in the lemma, and let f 2 a. On applying the division algorithm, wefind

f D a1g1C�� �CasgsC r; ai ; r 2 kŒX1; : : : ;Xn�;

where either r D 0 or no monomial occurring in it is divisible by any LT.gi /. But r D f �Paigi 2

a, and therefore LT.r/ 2 LT.a/D .LT.g1/; : : : ;LT.gs//, which, according to Lemma 1.43, impliesthat every monomial occurring in r is divisible by one in LT.gi /. Thus r D 0, and g 2 .g1; : : : ;gs/.2

Standard (Grobner) bases

Fix a monomial ordering of kŒX1; : : : ;Xn�.

DEFINITION 1.48. A finite subset S D fg1; : : : ;gsg of an ideal a is a standard (Grobner, Groebner,Grobner) basis8 for a if

.LT.g1/; : : : ;LT.gs//D LT.a/:

In other words, S is a standard basis if the leading term of every element of a is divisible by at leastone of the leading terms of the gi .

THEOREM 1.49. Every ideal has a standard basis, and it generates the ideal; if fg1; : : : ;gsg is astandard basis for an ideal a, then f 2 a ” the remainder on division by the gi is 0.

PROOF. Our proof of the Hilbert basis theorem shows that every ideal has a standard basis, andthat it generates the ideal. Let f 2 a. The argument in the same proof, that the remainder of f ondivision by g1; : : : ;gs is 0, used only that fg1; : : : ;gsg is a standard basis for a. 2

REMARK 1.50. The proposition shows that, for f 2 a, the remainder of f on division by fg1; : : : ;gsgis independent of the order of the gi (in fact, it’s always zero). This is not true if f … a — see theexample using Maple at the end of this chapter.

Let a D .f1; : : : ;fs/. Typically, ff1; : : : ;fsg will fail to be a standard basis because in someexpression

cX˛fi �dXˇfj ; c;d 2 k; (**)

the leading terms will cancel, and we will get a new leading term not in the ideal generated by theleading terms of the fi . For example,

X2 DX � .X2Y CX �2Y 2/�Y � .X3�2XY /

is in the ideal generated by X2Y CX � 2Y 2 and X3� 2XY but it is not in the ideal generated bytheir leading terms.

There is an algorithm for transforming a set of generators for an ideal into a standard basis,which, roughly speaking, makes adroit use of equations of the form (**) to construct enough newelements to make a standard basis — see Cox et al. 1992, pp80–87.

We now have an algorithm for deciding whether f 2 .f1; : : : ;fr /. First transform ff1; : : : ;frginto a standard basis fg1; : : : ;gsg; and then divide f by g1; : : : ;gs to see whether the remainder is0 (in which case f lies in the ideal) or nonzero (and it doesn’t). This algorithm is implemented inMaple — see below.

A standard basis fg1; : : : ;gsg is minimal if each gi has leading coefficient 1 and, for all i , theleading term of gi does not belong to the ideal generated by the leading terms of the remainingg’s. A standard basis fg1; : : : ;gsg is reduced if each gi has leading coefficient 1 and if, for all i , nomonomial of gi lies in the ideal generated by the leading terms of the remaining g’s. One can prove(Cox et al. 1992, p91) that every nonzero ideal has a unique reduced standard basis.

8Standard bases were first introduced (under that name) by Hironaka in the mid-1960s, and independently,but slightly later, by Buchberger in his Ph.D. thesis. Buchberger named them after his thesis adviser Grobner.

36 1. PRELIMINARIES

REMARK 1.51. Consider polynomials f;g1; : : : ;gs 2 kŒX1; : : : ;Xn�. The algorithm that replacesg1; : : : ;gs with a standard basis works entirely within kŒX1; : : : ;Xn�, i.e., it doesn’t require a fieldextension. Likewise, the division algorithm doesn’t require a field extension. Because these opera-tions give well-defined answers, whether we carry them out in kŒX1; : : : ;Xn� or in KŒX1; : : : ;Xn�,K � k, we get the same answer. Maple appears to work in the subfield of C generated over Q by allthe constants occurring in the polynomials.

We conclude this chapter with the annotated transcript of a session in Maple applying the abovealgorithm to show that

q D 3x3yz2�xz2Cy3Cyz

doesn’t lie in the ideal.x2�2xzC5;xy2Cyz3;3y2�8z3/:

A Maple session>with(grobner):

This loads the grobner package, and lists the available commands:finduni, finite, gbasis, gsolve, leadmon, normalf, solvable, spoly

To discover the syntax of a command, a brief description of the command, and an example, type“?command;”

>G:=gbasis([x^2-2*x*z+5,x*y^2+y*z^3,3*y^2-8*z^3],[x,y,z]);

G WD Œx2�2xzC5;�3y2C8z3;8xy2C3y3;9y4C48zy3C320y2�

This asks Maple to find the reduced Grobner basis for the ideal generated by the three polynomialslisted, with respect to the symbols listed (in that order). It will automatically use grevlex order unlessyou add ,plex to the command.

> q:=3*x^3*y*z^2 - x*z^2 + y^3 + y*z;

q WD 3x3yz2�xz2Cy3C zy

This defines the polynomial q.> normalf(q,G,[x,y,z]);

9z2y3�15yz2x� 414y3C60y2z�xz2Czy

Asks for the remainder when q is divided by the polynomials listed in G using the symbols listed.This particular example is amusing — the program gives different orderings for G, and differentanswers for the remainder, depending on which computer I use. This is O.K., because, since q isn’tin the ideal, the remainder may depend on the ordering of G.

Notes:

(a) To start Maple on a Unix computer type “maple”; to quit type “quit”.

(b) Maple won’t do anything until you type “;” or “:” at the end of a line.

(c) The student version of Maple is quite cheap, but unfortunately, it doesn’t have the Grobnerpackage.

(d) For more information on Maple:

i) There is a brief discussion of the Grobner package in Cox et al. 1992, Appendix C, �1.ii) The Maple V Library Reference Manual pp469–478 briefly describes what the Grobner

package does (exactly the same information is available on line, by typing ?command).iii) There are many books containing general introductions to Maple syntax.

(e) Grobner bases are also implemented in Macsyma, Mathematica, and Axiom, but for seriouswork it is better to use one of the programs especially designed for Grobner basis computa-tion, namely,

CoCoA (Computations in Commutative Algebra) http://cocoa.dima.unige.it/.Macaulay 2 (Grayson and Stillman) http://www.math.uiuc.edu/Macaulay2/.

Exercises 37

Exercises

1-1. Let k be an infinite field (not necessarily algebraically closed). Show that an f 2kŒX1; : : : ;Xn� that is identically zero on kn is the zero polynomial (i.e., has all its coeffi-cients zero).

1-2. Find a minimal set of generators for the ideal

.XC2Y;3XC6Y C3Z;2XC4Y C3Z/

in kŒX;Y;Z�. What standard algorithm in linear algebra will allow you to answer thisquestion for any ideal generated by homogeneous linear polynomials? Find a minimal setof generators for the ideal

.XC2Y C1;3XC6Y C3XC2;2XC4Y C3ZC3/:

CHAPTER 2Algebraic Sets

In this chapter, k is an algebraically closed field.

Definition of an algebraic set

An algebraic subset V.S/ of kn is the set of common zeros of some set S of polynomialsin kŒX1; : : : ;Xn�:

V.S/D f.a1; : : : ;an/ 2 knj f .a1; : : : ;an/D 0 all f .X1; : : : ;Xn/ 2 Sg:

Note thatS � S 0 H) V.S/� V.S 0/I

— more equations means fewer solutions.Recall that the ideal a generated by a set S consists of all finite sumsX

figi ; fi 2 kŒX1; : : : ;Xn�; gi 2 S:

Such a sumPfigi is zero at every point at which the gi are all zero, and so V.S/� V.a/,

but the reverse conclusion is also true because S � a. Thus V.S/ D V.a/ — the zero setof S is the same as that of the ideal generated by S . Hence the algebraic sets can also bedescribed as the sets of the form V.a/, a an ideal in kŒX1; : : : ;Xn�.

EXAMPLE 2.1. (a) If S is a system of homogeneous linear equations, then V.S/ is a sub-space of kn. If S is a system of nonhomogeneous linear equations, then V.S/ is eitherempty or is the translate of a subspace of kn.

(b) If S consists of the single equation

Y 2 DX3CaXCb; 4a3C27b2 ¤ 0;

then V.S/ is an elliptic curve. For more on elliptic curves, and their relation to Fermat’s lasttheorem, see my notes on Elliptic Curves. The reader should sketch the curve for particularvalues of a and b. We generally visualize algebraic sets as though the field k were R,although this can be misleading.

(c) For the empty set ;, V.;/D kn.(d) The algebraic subsets of k are the finite subsets (including ;/ and k itself.

39

40 2. ALGEBRAIC SETS

(e) Some generating sets for an ideal will be more useful than others for determiningwhat the algebraic set is. For example, a Grobner basis for the ideal

aD .X2CY 2CZ2�1; X2CY 2�Y; X �Z/

is (according to Maple)

X �Z; Y 2�2Y C1; Z2�1CY:

The middle polynomial has (double) root 1, and it follows easily that V.a/ consists of thesingle point .0;1;0/.

The Hilbert basis theorem

In our definition of an algebraic set, we didn’t require the set S of polynomials to be finite,but the Hilbert basis theorem shows that every algebraic set will also be the zero set of a fi-nite set of polynomials. More precisely, the theorem shows that every ideal in kŒX1; : : : ;Xn�can be generated by a finite set of elements, and we have already observed that any set ofgenerators of an ideal has the same zero set as the ideal.

We sketched an algorithmic proof of the Hilbert basis theorem in the last chapter. Herewe give the slick proof.

THEOREM 2.2 (HILBERT BASIS THEOREM). The ring kŒX1; : : : ;Xn� is noetherian, i.e.,every ideal is finitely generated.

Since k itself is noetherian, and kŒX1; : : : ;Xn�1�ŒXn� D kŒX1; : : : ;Xn�, the theoremfollows by induction from the next lemma.

LEMMA 2.3. If A is noetherian, then so also is AŒX�.

PROOF. Recall that for a polynomial

f .X/D a0XrCa1X

r�1C�� �Car ; ai 2 A; a0 ¤ 0;

r is called the degree of f , and a0 is its leading coefficient.Let a be a proper ideal in AŒX�, and let ai be the set of elements of A that occur as the

leading coefficient of a polynomial in a of degree � i . Then ai is an ideal in A, and

a1 � a2 � �� � � ai � �� � :

Because A is noetherian, this sequence eventually becomes constant, say ad D adC1 D : : :(and ad consists of the leading coefficients of all polynomials in a).

For each i � d , choose a finite set fi1;fi2; : : : of polynomials in a of degree i such thatthe leading coefficients aij of the fij ’s generate ai .

Let f 2 a; we shall prove by induction on the degree of f that it lies in the idealgenerated by the fij . When f has degree 0, it is zero, and so lies in .fij /.

Suppose that f has degree s � d . Then f D aXsC�� � with a 2 ad , and so

aDX

jbjadj ; some bj 2 A.

The Zariski topology 41

Nowf �

XjbjfdjX

s�d

has degree < deg.f /, and so lies in .fij / by induction.Suppose that f has degree s � d . Then a similar argument shows that

f �X

bjfsj

has degree < deg.f / for suitable bj 2 A, and so lies in .fij / by induction. 2

ASIDE 2.4. One may ask how many elements are needed to generate a given ideal a inkŒX1; : : : ;Xn�, or, what is not quite the same thing, how many equations are needed todefine a given algebraic set V . When n D 1, we know that every ideal is generated by asingle element. Also, if V is a linear subspace of kn, then linear algebra shows that it is thezero set of n�dim.V / polynomials. All one can say in general, is that at least n�dim.V /polynomials are needed to define V (see 9.7), but often more are required. Determiningexactly how many is an area of active research — see (9.14).

The Zariski topology

PROPOSITION 2.5. There are the following relations:

(a) a� b H) V.a/� V.b/I(b) V.0/D kn; V.kŒX1; : : : ;Xn�/D ;I

(c) V.ab/D V.a\b/D V.a/[V.b/I(d) V.

Pi2I ai /D

Ti2I V.ai / for every family of ideals .ai /i2I .

PROOF. The first two statements are obvious. For (c), note that

ab� a\b� a;b H) V.ab/� V.a\b/� V.a/[V.b/:

For the reverse inclusions, observe that if a … V.a/[V.b/, then there exist f 2 a, g 2 bsuch that f .a/ ¤ 0, g.a/ ¤ 0; but then .fg/.a/ ¤ 0, and so a … V.ab/. For (d) recallthat, by definition,

Pai consists of all finite sums of the form

Pfi , fi 2 ai . Thus (d) is

obvious. 2

Statements (b), (c), and (d) show that the algebraic subsets of kn satisfy the axioms to bethe closed subsets for a topology on kn: both the whole space and the empty set are closed;a finite union of closed sets is closed; an arbitrary intersection of closed sets is closed. Thistopology is called the Zariski topology on kn. The induced topology on a subset V of kn

is called the Zariski topology on V .The Zariski topology has many strange properties, but it is nevertheless of great impor-

tance. For the Zariski topology on k, the closed subsets are just the finite sets and the wholespace, and so the topology is not Hausdorff. We shall see in (2.29) below that the properclosed subsets of k2 are finite unions of (isolated) points and curves (zero sets of irreduciblef 2 kŒX;Y �). Note that the Zariski topologies on C and C2 are much coarser (have manyfewer open sets) than the complex topologies.

42 2. ALGEBRAIC SETS

The Hilbert Nullstellensatz

We wish to examine the relation between the algebraic subsets of kn and the ideals ofkŒX1; : : : ;Xn�, but first we consider the question of when a set of polynomials has a commonzero, i.e., when the equations

g.X1; : : : ;Xn/D 0; g 2 a;

are “consistent”. Obviously, the equations

gi .X1; : : : ;Xn/D 0; i D 1; : : : ;m

are inconsistent if there exist fi 2 kŒX1; : : : ;Xn� such thatPfigi D 1, i.e., if 12 .g1; : : : ;gm/

or, equivalently, .g1; : : : ;gm/ D kŒX1; : : : ;Xn�. The next theorem provides a converse tothis.

THEOREM 2.6 (HILBERT NULLSTELLENSATZ). 1 Every proper ideal a in kŒX1; : : : ;Xn�has a zero in kn.

A point P D .a1; : : : ;an/ in kn defines a homomorphism “evaluate at P ”

kŒX1; : : : ;Xn�! k; f .X1; : : : ;Xn/ 7! f .a1; : : : ;an/;

whose kernel contains a ifP 2V.a/. Conversely, from a homomorphism 'WkŒX1; : : : ;Xn�!

k of k-algebras whose kernel contains a, we obtain a point P in V.a/, namely,

P D .'.X1/; : : : ;'.Xn//:

Thus, to prove the theorem, we have to show that there exists a k-algebra homomorphismkŒX1; : : : ;Xn�=a! k.

Since every proper ideal is contained in a maximal ideal, it suffices to prove this fora maximal ideal m. Then K def

D kŒX1; : : : ;Xn�=m is a field, and it is finitely generated asan algebra over k (with generators X1Cm; : : : ;XnCm/. To complete the proof, we mustshow K D k. The next lemma accomplishes this.

Although we shall apply the lemma only in the case that k is algebraically closed, inorder to make the induction in its proof work, we need to allow arbitrary k’s in the statement.

LEMMA 2.7 (ZARISKI’S LEMMA). Let k �K be fields (k is not necessarily algebraicallyclosed). If K is finitely generated as an algebra over k, then K is algebraic over k. (HenceK D k if k is algebraically closed.)

PROOF. We shall prove this by induction on r , the minimum number of elements requiredto generate K as a k-algebra. The case r D 0 being trivial, we may suppose that K DkŒx1; : : : ;xr � with r � 1. If K is not algebraic over k, then at least one xi , say x1, is notalgebraic over k. Then, kŒx1� is a polynomial ring in one symbol over k, and its field offractions k.x1/ is a subfield of K. Clearly K is generated as a k.x1/-algebra by x2; : : : ;xr ,and so the induction hypothesis implies that x2; : : : ;xr are algebraic over k.x1/. Accordingto (1.18), there exists a d 2 kŒx1� such that dxi is integral over kŒx1� for all i � 2. Letf 2 K D kŒx1; : : : ;xr �. For a sufficiently large N , dNf 2 kŒx1;dx2; : : : ;dxr �, and so

1Nullstellensatz = zero-points-theorem.

The correspondence between algebraic sets and ideals 43

dNf is integral over kŒx1� (1.16). When we apply this statement to an element f of k.x1/,(1.21) shows that dNf 2 kŒx1�. Therefore, k.x1/ D

SN d�NkŒx1�, but this is absurd,

because kŒx1� (' kŒX�/ has infinitely many distinct monic irreducible polynomials2 thatcan occur as denominators of elements of k.x1/. 2

The correspondence between algebraic sets and ideals

For a subset W of kn, we write I.W / for the set of polynomials that are zero on W :

I.W /D ff 2 kŒX1; : : : ;Xn� j f .P /D 0 all P 2W g:

Clearly, it is an ideal in kŒX1; : : : ;Xn�. There are the following relations:

(a) V �W H) I.V /� I.W /I

(b) I.;/D kŒX1; : : : ;Xn�; I.kn/D 0I(c) I.

SWi /D

TI.Wi /.

Only the statement I.kn/ D 0 is (perhaps) not obvious. It says that, if a polynomial isnonzero (in the ring kŒX1; : : : ;Xn�), then it is nonzero at some point of kn. This is truewith k any infinite field (see Exercise 1-1). Alternatively, it follows from the strong HilbertNullstellensatz (cf. 2.14a below).

EXAMPLE 2.8. Let P be the point .a1; : : : ;an/. Clearly I.P / � .X1�a1; : : : ;Xn�an/,but .X1�a1; : : : ;Xn�an/ is a maximal ideal, because “evaluation at .a1; : : : ;an/” definesan isomorphism

kŒX1; : : : ;Xn�=.X1�a1; : : : ;Xn�an/! k:

As I.P / is a proper ideal, it must equal .X1�a1; : : : ;Xn�an/:

PROPOSITION 2.9. For every subset W � kn, VI.W / is the smallest algebraic subset ofkn containing W . In particular, VI.W /DW if W is an algebraic set.

PROOF. Let V be an algebraic set containing W , and write V D V.a/. Then a � I.W /,and so V.a/� VI.W /. 2

The radical rad.a/ of an ideal a is defined to be

ff j f r 2 a, some r 2 N, r > 0g:

PROPOSITION 2.10. Let a be an ideal in a ring A.(a) The radical of a is an ideal.(b) rad.rad.a//D rad.a/.

PROOF. (a) If a 2 rad.a/, then clearly fa 2 rad.a/ for all f 2 A. Suppose a;b 2 rad.a/,with say ar 2 a and bs 2 a. When we expand .aCb/rCs using the binomial theorem, wefind that every term has a factor ar or bs , and so lies in a.

(b) If ar 2 rad.a/, then ars D .ar/s 2 a for some s. 2

2If k is infinite, then consider the polynomials X �a, and if k is finite, consider the minimum polynomialsof generators of the extension fields of k. Alternatively, and better, adapt Euclid’s proof that there are infinitelymany prime numbers.

44 2. ALGEBRAIC SETS

An ideal is said to be radical if it equals its radical, i.e., if f r 2 a H) f 2 a. Equiva-lently, a is radical if and only if A=a is a reduced ring, i.e., a ring without nonzero nilpotentelements (elements some power of which is zero). Since integral domains are reduced,prime ideals (a fortiori maximal ideals) are radical.

If a and b are radical, then a\b is radical, but aCb need not be: consider, for example,a D .X2�Y / and b D .X2CY /; they are both prime ideals in kŒX;Y �, but X2 2 aC b,X … aCb.

As f r.P /D f .P /r , f r is zero wherever f is zero, and so I.W / is radical. In partic-ular, IV.a/� rad.a/. The next theorem states that these two ideals are equal.

THEOREM 2.11 (STRONG HILBERT NULLSTELLENSATZ). For every ideal a in kŒX1; : : : ;Xn�,IV.a/ is the radical of a; in particular, IV.a/D a if a is a radical ideal.

PROOF. We have already noted that IV.a/ � rad.a/. For the reverse inclusion, we haveto show that if h is identically zero on V.a/, then hN 2 a for some N > 0; here h 2kŒX1; : : : ;Xn�. We may assume h ¤ 0. Let g1; : : : ;gm generate a, and consider the sys-tem of mC1 equations in nC1 variables, X1; : : : ;Xn;Y;�

gi .X1; : : : ;Xn/ D 0; i D 1; : : : ;m

1�Yh.X1; : : : ;Xn/ D 0:

If .a1; : : : ;an;b/ satisfies the first m equations, then .a1; : : : ;an/ 2 V.a/; consequently,h.a1; : : : ;an/ D 0, and .a1; : : : ;an;b/ doesn’t satisfy the last equation. Therefore, theequations are inconsistent, and so, according to the original Nullstellensatz, there existfi 2 kŒX1; : : : ;Xn;Y � such that

1D

mXiD1

figi CfmC1 � .1�Yh/

(in the ring kŒX1; : : : ;Xn;Y �). On applying the homomorphism�Xi 7!XiY 7! h�1

WkŒX1; : : : ;Xn;Y �! k.X1; : : : ;Xn/

to the above equality, we obtain the identity

1D

mXiD1

fi .X1; : : : ;Xn;h�1/ �gi .X1; : : : ;Xn/ (*)

in k.X1; : : : ;Xn/. Clearly

fi .X1; : : : ;Xn;h�1/D

polynomial in X1; : : : ;XnhNi

for some Ni . Let N be the largest of the Ni . On multiplying (*) by hN we obtain anequation

hN DX

(polynomial in X1; : : : ;Xn/ �gi .X1; : : : ;Xn/;

which shows that hN 2 a. 2

The correspondence between algebraic sets and ideals 45

COROLLARY 2.12. The map a 7! V.a/ defines a one-to-one correspondence between theset of radical ideals in kŒX1; : : : ;Xn� and the set of algebraic subsets of kn; its inverse is I .

PROOF. We know that IV.a/D a if a is a radical ideal (2.11), and that VI.W /DW if Wis an algebraic set (2.9). Therefore, I and V are inverse maps. 2

COROLLARY 2.13. The radical of an ideal in kŒX1; : : : ;Xn� is equal to the intersection ofthe maximal ideals containing it.

PROOF. Let a be an ideal in kŒX1; : : : ;Xn�. Because maximal ideals are radical, everymaximal ideal containing a also contains rad.a/:

rad.a/�\m�a

m.

For each P D .a1; : : : ;an/ 2 kn, mP D .X1� a1; : : : ;Xn� an/ is a maximal ideal inkŒX1; : : : ;Xn�, and

f 2mP ” f .P /D 0

(see 2.8). ThusmP � a ” P 2 V.a/.

If f 2mP for all P 2 V.a/, then f is zero on V.a/, and so f 2 IV.a/D rad.a/. We haveshown that

rad.a/�\

P2V.a/

mP :

2

REMARK 2.14. (a) Because V.0/D kn,

I.kn/D IV.0/D rad.0/D 0I

in other words, only the zero polynomial is zero on the whole of kn.(b) The one-to-one correspondence in the corollary is order inverting. Therefore the

maximal proper radical ideals correspond to the minimal nonempty algebraic sets. Butthe maximal proper radical ideals are simply the maximal ideals in kŒX1; : : : ;Xn�, and theminimal nonempty algebraic sets are the one-point sets. As

I..a1; : : : ;an//D .X1�a1; : : : ;Xn�an/

(see 2.8), this shows that the maximal ideals of kŒX1; : : : ;Xn� are exactly the ideals of theform .X1�a1; : : : ;Xn�an/.

(c) The algebraic set V.a/ is empty if and only if aD kŒX1; : : : ;Xn�, because

V.a/D ;) rad.a/D kŒX1; : : : ;Xn�) 1 2 rad.a/) 1 2 a:

(d) Let W and W 0 be algebraic sets. Then W \W 0 is the largest algebraic subset con-tained in both W and W 0, and so I.W \W 0/ must be the smallest radical ideal containingboth I.W / and I.W 0/. Hence I.W \W 0/D rad.I.W /CI.W 0//.

For example, letW DV.X2�Y / andW 0DV.X2CY /; then I.W \W 0/D rad.X2;Y /D.X;Y / (assuming characteristic ¤ 2/. Note that W \W 0 D f.0;0/g, but when realized asthe intersection of Y DX2 and Y D�X2, it has “multiplicity 2”. [The reader should drawa picture.]

46 2. ALGEBRAIC SETS

ASIDE 2.15. LetP be the set of subsets of kn and letQ be the set of subsets of kŒX1; : : : ;Xn�.Then I WP ! Q and V WQ ! P define a simple Galois correspondence (cf. FT 7.17).Therefore, I and V define a one-to-one correspondence between IP and VQ. But thestrong Nullstellensatz shows that IP consists exactly of the radical ideals, and (by defini-tion) VQ consists of the algebraic subsets. Thus we recover Corollary 2.12.

Finding the radical of an ideal

Typically, an algebraic set V will be defined by a finite set of polynomials fg1; : : : ;gsg, andthen we shall need to find I.V /D rad..g1; : : : ;gs//.

PROPOSITION 2.16. The polynomial h 2 rad.a/ if and only if 1 2 .a;1�Yh/ (the ideal inkŒX1; : : : ;Xn;Y � generated by the elements of a and 1�Yh).

PROOF. We saw that 1 2 .a;1� Yh/ implies h 2 rad.a/ in the course of proving (2.11).Conversely, if hN 2 a, then

1D Y NhN C .1�Y NhN /

D Y NhN C .1�Yh/ � .1CYhC�� �CY N�1hN�1/

2 aC .1�Yh/: 2

Since we have an algorithm for deciding whether or not a polynomial belongs to anideal given a set of generators for the ideal – see Section 1 – we also have an algorithmdeciding whether or not a polynomial belongs to the radical of the ideal, but not yet analgorithm for finding a set of generators for the radical. There do exist such algorithms(see Cox et al. 1992, p177 for references), and one has been implemented in the computeralgebra system Macaulay 2 (see p36).

The Zariski topology on an algebraic set

We now examine more closely the Zariski topology on kn and on an algebraic subset ofkn. Proposition 2.9 says that, for each subset W of kn, VI.W / is the closure of W , and(2.12) says that there is a one-to-one correspondence between the closed subsets of kn andthe radical ideals of kŒX1; : : : ;Xn�. Under this correspondence, the closed subsets of analgebraic set V correspond to the radical ideals of kŒX1; : : : ;Xn� containing I.V /.

PROPOSITION 2.17. Let V be an algebraic subset of kn.(a) The points of V are closed for the Zariski topology (thus V is a T1-space).(b) Every ascending chain of open subsets U1 � U2 � �� � of V eventually becomes

constant, i.e., for some m, Um D UmC1 D �� � ; hence every descending chain of closedsubsets of V eventually becomes constant.

(c) Every open covering of V has a finite subcovering.

PROOF. (a) Clearly f.a1; : : : ;an/g is the algebraic set defined by the ideal .X1�a1; : : : ;Xn�an/.

(b) A sequence V1 � V2 � �� � of closed subsets of V gives rise to a sequence of radicalideals I.V1/ � I.V2/ � : : :, which eventually becomes constant because kŒX1; : : : ;Xn� isnoetherian.

The coordinate ring of an algebraic set 47

(c) Let V DSi2I Ui with each Ui open. Choose an i0 2 I ; if Ui0 ¤ V , then there

exists an i1 2 I such that Ui0 &Ui0[Ui1 . If Ui0[Ui1 ¤ V , then there exists an i2 2 I etc..Because of (b), this process must eventually stop. 2

A topological space having the property (b) is said to be noetherian. The conditionis equivalent to the following: every nonempty set of closed subsets of V has a minimalelement. A space having property (c) is said to be quasicompact (by Bourbaki at least;others call it compact, but Bourbaki requires a compact space to be Hausdorff). The proofof (c) shows that every noetherian space is quasicompact. Since an open subspace of anoetherian space is again noetherian, it will also be quasicompact.

The coordinate ring of an algebraic set

Let V be an algebraic subset of kn, and let I.V /D a. The coordinate ring of V is

kŒV �D kŒX1; : : : ;Xn�=a.

This is a finitely generated reduced k-algebra (because a is radical), but it need not be anintegral domain.

A function V ! k of the form P 7! f .P / for some f 2 kŒX1; : : : ;Xn� is said tobe regular.3 Two polynomials f;g 2 kŒX1; : : : ;Xn� define the same regular function onV if only if they define the same element of kŒV �. The coordinate function xi WV ! k,.a1; : : : ;an/ 7! ai is regular, and kŒV �' kŒx1; : : : ;xn�.

For an ideal b in kŒV �, set

V.b/D fP 2 V j f .P /D 0, all f 2 bg:

Let W D V.b/. The maps

kŒX1; : : : ;Xn�! kŒV �DkŒX1; : : : ;Xn�

a! kŒW �D

kŒV �

b

send a regular function on kn to its restriction to V , and then to its restriction to W .Write � for the map kŒX1; : : : ;Xn�! kŒV �. Then b 7! ��1.b/ is a bijection from the

set of ideals of kŒV � to the set of ideals of kŒX1; : : : ;Xn� containing a, under which radical,prime, and maximal ideals correspond to radical, prime, and maximal ideals (each of theseconditions can be checked on the quotient ring, and kŒX1; : : : ;Xn�=��1.b/ ' kŒV �=b).Clearly

V.��1.b//D V.b/;

and so b 7! V.b/ is a bijection from the set of radical ideals in kŒV � to the set of algebraicsets contained in V .

For h 2 kŒV �, setD.h/D fa 2 V j h.a/¤ 0g:

It is an open subset of V , because it is the complement of V..h//, and it is empty if andonly if h is zero (2.14a).

3In the next chapter, we’ll give a more general definition of regular function according to which these areexactly the regular functions on V , and so kŒV � will be the ring of regular functions on V .

48 2. ALGEBRAIC SETS

PROPOSITION 2.18. (a) The points of V are in one-to-one correspondence with the maxi-mal ideals of kŒV �.

(b) The closed subsets of V are in one-to-one correspondence with the radical ideals ofkŒV �.

(c) The sets D.h/, h 2 kŒV �, are a base for the topology on V , i.e., each D.h/ is open,and every open set is a union (in fact, a finite union) of D.h/’s.

PROOF. (a) and (b) are obvious from the above discussion. For (c), we have already ob-served thatD.h/ is open. Any other open set U � V is the complement of a set of the formV.b/, with b an ideal in kŒV �, and if f1; : : : ;fm generate b, then U D

SD.fi /. 2

The D.h/ are called the basic (or principal) open subsets of V . We sometimes writeVh for D.h/. Note that

D.h/�D.h0/ ” V.h/� V.h0/

” rad..h//� rad..h0//

” hr 2 .h0/ some r

” hr D h0g, some g:

Some of this should look familiar: if V is a topological space, then the zero set of afamily of continuous functions f WV ! R is closed, and the set where such a function isnonzero is open.

Irreducible algebraic sets

A nonempty topological space is said to be irreducible if it is not the union of two properclosed subsets; equivalently, if any two nonempty open subsets have a nonempty intersec-tion, or if every nonempty open subset is dense. By convention, the empty space is notirreducible.

If an irreducible space W is a finite union of closed subsets, W DW1[ : : :[Wr , thenW DW1 or W2[ : : :[Wr ; if the latter, then W DW2 or W3[ : : :[Wr , etc.. Continuing inthis fashion, we find that W DWi for some i .

The notion of irreducibility is not useful for Hausdorff topological spaces, because theonly irreducible Hausdorff spaces are those consisting of a single point – two points wouldhave disjoint open neighbourhoods contradicting the second condition.

PROPOSITION 2.19. An algebraic set W is irreducible and only if I.W / is prime.

PROOF. H) : Suppose fg 2 I.W /. At each point of W , either f is zero or g is zero, andso W � V.f /[V.g/. Hence

W D .W \V.f //[ .W \V.g//:

As W is irreducible, one of these sets, say W \V.f /, must equal W . But then f 2 I.W /.This shows that I.W / is prime.(H: Suppose W D V.a/[V.b/ with a and b radical ideals — we have to show that

W equals V.a/ or V.b/. Recall (2.5) that V.a/[V.b/D V.a\b/ and that a\b is radical;hence I.W /D a\b. If W ¤ V.a/, then there is an f 2 arI.W /. For all g 2 b,

fg 2 a\bD I.W /:

Irreducible algebraic sets 49

Because I.W / is prime, this implies that b� I.W /; therefore W � V.b/. 2

Thus, there are one-to-one correspondences

radical ideals $ algebraic subsets

prime ideals $ irreducible algebraic subsets

maximal ideals $ one-point sets:

These correspondences are valid whether we mean ideals in kŒX1; : : : ;Xn� and algebraicsubsets of kn, or ideals in kŒV � and algebraic subsets of V . Note that the last correspon-dence implies that the maximal ideals in kŒV � are those of the form .x1�a1; : : : ;xn�an/,.a1; : : : ;an/ 2 V .

EXAMPLE 2.20. Let f 2 kŒX1; : : : ;Xn�. As we showed in (1.14), kŒX1; : : : ;Xn� is aunique factorization domain, and so .f / is a prime ideal if and only if f is irreducible(1.15). Thus

f is irreducible H) V.f / is irreducible.

On the other hand, suppose f factors,

f DYfmii ; fi distinct irreducible polynomials.

Then

.f /D\.f

mii /; .f

mii / distinct primary4ideals,

rad..f //D\.fi /; .fi / distinct prime ideals,

V.f /D[V.fi /; V .fi / distinct irreducible algebraic sets.

PROPOSITION 2.21. Let V be a noetherian topological space. Then V is a finite unionof irreducible closed subsets, V D V1[ : : :[Vm. Moreover, if the decomposition is irre-dundant in the sense that there are no inclusions among the Vi , then the Vi are uniquelydetermined up to order.

PROOF. Suppose that V can not be written as a finite union of irreducible closed subsets.Then, because V is noetherian, there will be a closed subsetW of V that is minimal amongthose that cannot be written in this way. But W itself cannot be irreducible, and so W DW1[W2, with eachWi a proper closed subset ofW . From the minimality ofW , we deducethat each Wi is a finite union of irreducible closed subsets, and so therefore is W . We havearrived at a contradiction.

Suppose thatV D V1[ : : :[Vm DW1[ : : :[Wn

are two irredundant decompositions. Then Vi DSj .Vi \Wj /, and so, because Vi is ir-

reducible, Vi D Vi \Wj for some j . Consequently, there is a function f W f1; : : : ;mg !f1; : : : ;ng such that Vi � Wf .i/ for each i . Similarly, there is a function gW f1; : : : ;ng !f1; : : : ;mg such that Wj � Vg.j / for each j . Since Vi � Wf .i/ � Vgf .i/, we must havegf .i/D i and Vi DWf .i/; similarly fgD id. Thus f and g are bijections, and the decom-positions differ only in the numbering of the sets. 2

3In a noetherian ring A, a proper ideal q is said to primary if every zero-divisor in A=q is nilpotent.

50 2. ALGEBRAIC SETS

The Vi given uniquely by the proposition are called the irreducible components of V .They are the maximal closed irreducible subsets of V . In Example 2.20, the V.fi / are theirreducible components of V.f /.

COROLLARY 2.22. A radical ideal a in kŒX1; : : : ;Xn� is a finite intersection of prime ide-als, a D p1 \ : : :\ pn; if there are no inclusions among the pi , then the pi are uniquelydetermined up to order.

PROOF. Write V.a/ as a union of its irreducible components, V.a/DSVi , and take pi D

I.Vi /. 2

REMARK 2.23. (a) An irreducible topological space is connected, but a connected topo-logical space need not be irreducible. For example, V.X1X2/ is the union of the coor-dinate axes in k2, which is connected but not irreducible. An algebraic subset V of kn

is not connected if and only if there exist ideals a and b such that a\ b D I.V / andaCbD kŒX1; : : : ;Xn�.

(b) A Hausdorff space is noetherian if and only if it is finite, in which case its irreduciblecomponents are the one-point sets.

(c) In kŒX�, .f .X// is radical if and only if f is square-free, in which case f is aproduct of distinct irreducible polynomials, f D f1 : : :fr , and .f / D .f1/\ : : :\ .fr/ (apolynomial is divisible by f if and only if it is divisible by each fi ).

(d) In a noetherian ring, every proper ideal a has a decomposition into primary ideals:a D

Tqi (see CA �14). For radical ideals, this becomes a simpler decomposition into

prime ideals, as in the corollary. For an ideal .f / with f DQfmii , it is the decomposition

.f /DT.f

mii / noted in Example 2.20.

Dimension

We briefly introduce the notion of the dimension of an algebraic set. In Chapter 9 we shalldiscuss this in more detail.

Let V be an irreducible algebraic subset. Then I.V / is a prime ideal, and so kŒV � isan integral domain. Let k.V / be its field of fractions — k.V / is called the field of rationalfunctions on V . The dimension of V is defined to be the transcendence degree of k.V /over k (see FT, Chapter 8).5

EXAMPLE 2.24. (a) Let V D kn; then k.V /D k.X1; : : : ;Xn/, and so dim.V /D n.(b) If V is a linear subspace of kn (or a translate of such a subspace), then it is an easy

exercise to show that the dimension of V in the above sense is the same as its dimension inthe sense of linear algebra (in fact, kŒV � is canonically isomorphic to kŒXi1 ; : : : ;Xid � wherethe Xij are the “free” variables in the system of linear equations defining V — see 5.12).

In linear algebra, we justify saying V has dimension n by proving that its elementsare parametrized by n-tuples. It is not true in general that the points of an algebraic setof dimension n are parametrized by n-tuples. The most one can say is that there exists afinite-to-one map to kn (see 8.12).

(c) An irreducible algebraic set has dimension 0 if and only if it consists of a singlepoint. Certainly, for any point P 2 kn, kŒP �D k, and so k.P /D k: Conversely, suppose

5According to CA, 13.8, the transcendence degree of k.V / is equal to the Krull dimension of kŒV �; cf.2.30 below.

Dimension 51

V D V.p/, p prime, has dimension 0. Then k.V / is an algebraic extension of k, and soequals k. From the inclusions

k � kŒV �� k.V /D k

we see that kŒV � D k. Hence p is maximal, and we saw in (2.14b) that this implies thatV.p/ is a point.

The zero set of a single nonconstant nonzero polynomial f .X1; : : : ;Xn/ is called ahypersurface in kn.

PROPOSITION 2.25. An irreducible hypersurface in kn has dimension n�1.

PROOF. An irreducible hypersurface is the zero set of an irreducible polynomial f (see2.20). Let

kŒx1; : : : ;xn�D kŒX1; : : : ;Xn�=.f /; xi DXi Cp;

and let k.x1; : : : ;xn/ be the field of fractions of kŒx1; : : : ;xn�. Since f is not zero, someXi ,say, Xn, occurs in it. Then Xn occurs in every nonzero multiple of f , and so no nonzeropolynomial in X1; : : : ;Xn�1 belongs to .f /. This means that x1; : : : ;xn�1 are algebraicallyindependent. On the other hand, xn is algebraic over k.x1; : : : ;xn�1/, and so fx1; : : : ;xn�1gis a transcendence basis for k.x1; : : : ;xn/ over k. 2

For a reducible algebraic set V , we define the dimension of V to be the maximum ofthe dimensions of its irreducible components. When the irreducible components all havethe same dimension d , we say that V has pure dimension d .

PROPOSITION 2.26. If V is irreducible and Z is a proper algebraic subset of V , thendim.Z/ < dim.V /.

PROOF. We may assume that Z is irreducible. Then Z corresponds to a nonzero primeideal p in kŒV �, and kŒZ�D kŒV �=p.

WritekŒV �D kŒX1; : : : ;Xn�=I.V /D kŒx1; : : : ;xn�:

Let f 2 kŒV �. The image Nf of f in kŒV �=p D kŒZ� is the restriction of f to Z. Withthis notation, kŒZ� D kŒ Nx1; : : : ; Nxn�. Suppose that dimZ D d and that the Xi have beennumbered so that Nx1; : : : ; Nxd are algebraically independent (see FT 8.9) for the proof thatthis is possible). I will show that, for any nonzero f 2 p, the d C1 elements x1; : : : ;xd ;fare algebraically independent, which implies that dimV � d C1.

Suppose otherwise. Then there is a nontrivial algebraic relation among the xi and f ,which we can write

a0.x1; : : : ;xd /fmCa1.x1; : : : ;xd /f

m�1C�� �Cam.x1; : : : ;xd /D 0;

with ai .x1; : : : ;xd / 2 kŒx1; : : : ;xd � and not all zero. Because V is irreducible, kŒV � is anintegral domain, and so we can cancel a power of f if necessary to make am.x1; : : : ;xd /nonzero. On restricting the functions in the above equality to Z, i.e., applying the homo-morphism kŒV �! kŒZ�, we find that

am. Nx1; : : : ; Nxd /D 0;

which contradicts the algebraic independence of Nx1; : : : ; Nxd . 2

52 2. ALGEBRAIC SETS

PROPOSITION 2.27. Let V be an irreducible variety such that kŒV � is a unique factor-ization domain (for example, V D Ad ). If W � V is a closed subvariety of dimensiondimV �1, then I.W /D .f / for some f 2 kŒV �.

PROOF. We know that I.W /DTI.Wi / where the Wi are the irreducible components of

W , and so if we can prove I.Wi / D .fi / then I.W / D .f1 � � �fr/. Thus we may supposethatW is irreducible. Let pD I.W /; it is a prime ideal, and it is nonzero because otherwisedim.W / D dim.V /. Therefore it contains an irreducible polynomial f . From (1.15) weknow .f / is prime. If .f /¤ p , then we have

W D V.p/$ V..f //$ V;

and dim.W / < dim.V .f // < dimV (see 2.26), which contradicts the hypothesis. 2

EXAMPLE 2.28. Let F.X;Y / and G.X;Y / be nonconstant polynomials with no commonfactor. Then V.F.X;Y // has dimension 1 by (2.25), and so V.F.X;Y //\ V.G.X;Y //must have dimension zero; it is therefore a finite set.

EXAMPLE 2.29. We classify the irreducible closed subsets V of k2. If V has dimension2, then (by 2.26) it can’t be a proper subset of k2, so it is k2. If V has dimension 1,then V ¤ k2, and so I.V / contains a nonzero polynomial, and hence a nonzero irreduciblepolynomial f (being a prime ideal). Then V � V.f /, and so equals V.f /. Finally, if Vhas dimension zero, it is a point. Correspondingly, we can make a list of all the prime idealsin kŒX;Y �: they have the form .0/, .f / (with f irreducible), or .X �a;Y �b/.

ASIDE 2.30. Later (9.4) we shall show that if, in the situation of (2.26), Z is a maximalproper irreducible subset of V , then dimZ D dimV �1. This implies that the dimension ofan algebraic set V is the maximum length of a chain

V0 ' V1 ' � � �' Vd

with each Vi closed and irreducible and V0 an irreducible component of V . Note thatthis description of dimension is purely topological — it makes sense for every noetheriantopological space.

On translating the description in terms of ideals, we see immediately that the dimensionof V is equal to the Krull dimension of kŒV �—the maximal length of a chain of primeideals,

pd ' pd�1 ' � � �' p0:

Exercises

2-1. Find I.W /, where V D .X2;XY 2/. Check that it is the radical of .X2;XY 2/.

2-2. Identify km2

with the set of m�m matrices. Show that, for all r , the set of matriceswith rank � r is an algebraic subset of km

2

.

2-3. Let V D f.t; : : : ; tn/ j t 2 kg. Show that V is an algebraic subset of kn, and thatkŒV �� kŒX� (polynomial ring in one variable). (Assume k has characteristic zero.)

Exercises 53

2-4. Using only that kŒX;Y � is a unique factorization domain and the results of ��1,2,show that the following is a complete list of prime ideals in kŒX;Y �:

(a) .0/;(b) .f .X;Y // for f an irreducible polynomial;(c) .X �a;Y �b/ for a;b 2 k.

2-5. Let A and B be (not necessarily commutative)Q-algebras of finite dimension overQ,and let Qal be the algebraic closure of Q in C. Show that if HomC-algebras.A˝QC;B˝QC/¤ ;, then HomQal-algebras.A˝QQal;B˝QQal/¤ ;. (Hint: The proof takes only a fewlines.)

CHAPTER 3Affine Algebraic Varieties

In this chapter, we define the structure of a ringed space on an algebraic set, and then wedefine the notion of affine algebraic variety — roughly speaking, this is an algebraic set withno preferred embedding into kn. This is in preparation for �4, where we define an algebraicvariety to be a ringed space that is a finite union of affine algebraic varieties satisfying anatural separation axiom.

Ringed spaces

Let V be a topological space and k a field.

DEFINITION 3.1. Suppose that for every open subset U of V we have a set OV .U / offunctions U ! k. Then OV is called a sheaf of k-algebras if it satisfies the followingconditions:

(a) OV .U / is a k-subalgebra of the algebra of all k-valued functions on U , i.e., OV .U /contains the constant functions and, if f;g lie in OV .U /, then so also do f Cg andfg.

(b) If U 0 is an open subset of U and f 2OV .U /, then f jU 0 2OV .U 0/:(c) A function f WU ! k on an open subset U of V is in OV .U / if f jUi 2OV .Ui / for

all Ui in some open covering of U .

Conditions (b) and (c) require that a function f on U lies in OV .U / if and only if eachpoint P of U has a neighborhood UP such that f jUP lies in OV .UP /; in other words, thecondition for f to lie in OV .U / is local.

EXAMPLE 3.2. (a) Let V be any topological space, and for each open subset U of V letOV .U / be the set of all continuous real-valued functions on U . Then OV is a sheaf ofR-algebras.

(b) Recall that a function f WU ! R, where U is an open subset of Rn, is said tobe smooth (or infinitely differentiable) if its partial derivatives of all orders exist and arecontinuous. Let V be an open subset of Rn, and for each open subset U of V let OV .U /be the set of all smooth functions on U . Then OV is a sheaf of R-algebras.

(c) Recall that a function f WU ! C, where U is an open subset of Cn, is said to beanalytic (or holomorphic) if it is described by a convergent power series in a neighbourhood

55

56 3. AFFINE ALGEBRAIC VARIETIES

of each point of U . Let V be an open subset of Cn, and for each open subset U of V letOV .U / be the set of all analytic functions on U . Then OV is a sheaf of C-algebras.

(d) Nonexample: let V be a topological space, and for each open subset U of V letOV .U / be the set of all real-valued constant functions on U ; then OV is not a sheaf, unlessV is irreducible!1 When “constant” is replaced with “locally constant”, OV becomes asheaf of R-algebras (in fact, the smallest such sheaf).

A pair .V;OV / consisting of a topological space V and a sheaf of k-algebras will becalled a ringed space. For historical reasons, we often write � .U;OV / for OV .U / and callits elements sections of OV over U .

Let .V;OV / be a ringed space. For every open subset U of V , the restriction OV jU ofOV to U , defined by

� .U 0;OV jU/D � .U 0;OV /, all open U 0 � U;

is a sheaf again.Let .V;OV / be ringed space, and let P 2 V . Consider pairs .f;U / consisting of an open

neighbourhood U of P and an f 2OV .U /. We write .f;U /� .f 0;U 0/ if f jU 00 D f 0jU 00

for some open neighbourhood U 00 of P contained in U and U 0. This is an equivalencerelation, and an equivalence class of pairs is called a germ of a function at P (relative toOV ). The set of equivalence classes of such pairs forms a k-algebra denoted OV;P or OP .In all the interesting cases, it is a local ring with maximal ideal the set of germs that arezero at P .

In a fancier terminology,

OP D lim�!

OV .U /; (direct limit over open neighbourhoods U of P ).

A germ of a function at P is defined by a function f on a neigbourhood of P (section ofOV ), and two such functions define the same germ if and only if they agree in a possiblysmaller neighbourhood of P .

EXAMPLE 3.3. Let OV be the sheaf of holomorphic functions on V DC, and let c 2C. Apower series

Pn�0an.z� c/

n, an 2 C, is called convergent if it converges on some openneighbourhood of c. The set of such power series is a C-algebra, and I claim that it iscanonically isomorphic to the C-algebra of germs of functions Oc .

Let f be a holomorphic function on a neighbourhood U of c. Then f has a uniquepower series expansion f D

Pan.z�c/

n in some (possibly smaller) open neighbourhoodof c (Cartan 19632, II 2.6). Moreover, another holomorphic function f1 on a neighbourhoodU1 of c defines the same power series if and only if f1 and f agree on some neighbourhoodof c contained in U \U 0 (ibid. I 4.3). Thus we have a well-defined injective map from thering of germs of holomorphic functions at c to the ring of convergent power series, whichis obviously surjective.

1If V is reducible, then it contains disjoint open subsets, say U1 and U2. Let f be the function on the unionof U1 and U2 taking the constant value 1 on U1 and the constant value 2 on U2. Then f is not in OV .U1[U2/,and so condition 3.1c fails.

2Cartan, Henri. Elementary theory of analytic functions of one or several complex variables. Hermann,Paris; Addison-Wesley; 1963.

The ringed space structure on an algebraic set 57

The ringed space structure on an algebraic set

We now take k to be an algebraically closed field. Let V be an algebraic subset of kn. Anelement h of kŒV � defines functions

P 7! h.P /WV ! k, and P 7! 1=h.P /WD.h/! k:

Thus a pair of elements g;h 2 kŒV � with h¤ 0 defines a function

P 7!g.P /

h.P /WD.h/! k:

We say that a function f WU ! k on an open subset U of V is regular if it is of this formin a neighbourhood of each of its points, i.e., if for all P 2 U , there exist g;h 2 kŒV � withh.P /¤ 0 such that the functions f and g

hagree in a neighbourhood of P . Write OV .U /

for the set of regular functions on U .For example, if V D kn, then a function f WU ! k is regular at a point P 2 U if there

exist polynomials g.X1; : : : ;Xn/ and h.X1; : : : ;Xn/ with h.P /¤ 0 such that f .Q/D g.P /h.P /

for all Q in a neighbourhood of P .

PROPOSITION 3.4. The map U 7!OV .U / defines a sheaf of k-algebras on V .

PROOF. We have to check the conditions (3.1).(a) Clearly, a constant function is regular. Suppose f and f 0 are regular on U , and let

P 2 U . By assumption, there exist g;g0;h;h0 2 kŒV �, with h.P /¤ 0¤ h0.P / such that fand f 0 agree with g

hand g 0

h0respectively near P . Then f Cf 0 agrees with gh0Cg 0h

hh0near P ,

and so f Cf 0 is regular on U . Similarly ff 0 is regular on U . Thus OV .U / is a k-algebra.(b,c) It is clear from the definition that the condition for f to be regular is local. 2

Let g;h 2 kŒV � andm2N. Then P 7! g.P /=h.P /m is a regular function onD.h/, andwe’ll show that all regular functions on D.h/ are of this form, i.e., � .D.h/;OV /' kŒV �h.In particular, the regular functions on V itself are exactly those defined by elements of kŒV �.

LEMMA 3.5. The function P 7! g.P /=h.P /m on D.h/ is the zero function if and only ifand only if ghD 0 (in kŒV �) (and hence g=hm D 0 in kŒV �h).

PROOF. If g=hm is zero on D.h/, then gh is zero on V because h is zero on the comple-ment of D.h/. Therefore gh is zero in kŒV �. Conversely, if ghD 0, then g.P /h.P /D 0for all P 2 V , and so g.P /D 0 for all P 2D.h/. 2

The lemma shows that the canonical map kŒV �h! OV .D.h// is well-defined and in-jective. The next proposition shows that it is also surjective.

PROPOSITION 3.6. (a) The canonical map kŒV �h! � .D.h/;OV / is an isomorphism.(b) For every P 2 V , there is a canonical isomorphism OP ! kŒV �mP , where mP is

the maximal ideal I.P /.

58 3. AFFINE ALGEBRAIC VARIETIES

PROOF. (a) It remains to show that every regular function f on D.h/ arises from an ele-ment of kŒV �h. By definition, we know that there is an open covering D.h/D

SVi and el-

ements gi , hi 2 kŒV �with hi nowhere zero on Vi such that f jVi Dgihi

. We may assume thateach set Vi is basic, say, Vi DD.ai / for some ai 2 kŒV �. By assumption D.ai / �D.hi /,and so aNi D hig

0i for some N 2 N and g0i 2 kŒV � (see p48). On D.ai /,

f Dgi

hiDgig0i

hig0i

Dgig0i

aNi:

Note thatD.aNi /DD.ai /. Therefore, after replacing gi with gig0i and hi with aNi , we canassume that Vi DD.hi /.

We now have thatD.h/DSD.hi / and that f jD.hi /D

gihi

. BecauseD.h/ is quasicom-pact, we can assume that the covering is finite. As gi

hiDgjhj

onD.hi /\D.hj /DD.hihj /,we have (by Lemma 3.5) that

hihj .gihj �gjhi /D 0, i.e., hih2jgi D h2i hjgj : (*)

Because D.h/DSD.hi /D

SD.h2i /, the set V..h//D V..h21; : : : ;h

2m//, and so h lies in

rad.h21; : : : ;h2m/: there exist ai 2 kŒV � such that

hN D

mXiD1

aih2i : (**)

for some N . I claim that f is the function on D.h/ defined byPaigihihN

:

Let P be a point ofD.h/. Then P will be in one of theD.hi /, sayD.hj /. We have thefollowing equalities in kŒV �:

h2j

mXiD1

aigihi D

mXiD1

aigjh2i hj by (*)

D gjhjhN by (**).

But f jD.hj /Dgjhj

, i.e., f hj and gj agree as functions on D.hj /. Therefore we have thefollowing equality of functions on D.hj /:

h2j

mXiD1

aigihi D f h2jhN :

Since h2j is never zero on D.hj /, we can cancel it, to find that, as claimed, the functionf hN on D.hj / equals that defined by

Paigihi .

(b) In the definition of the germs of a sheaf at P , it suffices to consider pairs .f;U / withU lying in a some basis for the neighbourhoods of P , for example, the basis provided bythe basic open subsets. Therefore,

OP D lim�!

h.P /¤0

� .D.h/;OV /.a/' lim�!h…mP

kŒV �h1:29.b/' kŒV �mP :

2

The ringed space structure on an algebraic set 59

REMARK 3.7. Let V be an affine variety and P a point on V . Proposition 1.30 showsthat there is a one-to-one correspondence between the prime ideals of kŒV � contained inmP and the prime ideals of OP . In geometric terms, this says that there is a one-to-onecorrespondence between the prime ideals in OP and the irreducible closed subvarieties ofV passing through P .

REMARK 3.8. (a) Let V be an algebraic subset of kn, and let AD kŒV �. The propositionand (2.18) allow us to describe .V;OV / purely in terms of A:

˘ V is the set of maximal ideals in A; for each f 2 A, let D.f /D fm j f …mg;˘ the topology on V is that for which the sets D.f / form a base;˘ OV is the unique sheaf of k-algebras on V for which � .D.f /;OV /D Af .

(b) When V is irreducible, all the rings attached to it are subrings of the field k.V /. Inthis case,

� .D.h/;OV /Dng=hN 2 k.V / j g 2 kŒV �; N 2 N

oOP D fg=h 2 k.V / j h.P /¤ 0g

� .U;OV /D\

P2UOP

D

\� .D.hi /;OV / if U D

[D.hi /:

Note that every element of k.V / defines a function on some dense open subset of V . Fol-lowing tradition, we call the elements of k.V / rational functions on V .3 The equalitiesshow that the regular functions on an open U � V are the rational functions on V that aredefined at each point of U (i.e., lie in OP for each P 2 U ).

EXAMPLE 3.9. (a) Let V D kn. Then the ring of regular functions on V , � .V;OV /, iskŒX1; : : : ;Xn�. For every nonzero polynomial h.X1; : : : ;Xn/, the ring of regular functionson D.h/ is n

g=hN 2 k.X1; : : : ;Xn/ j g 2 kŒX1; : : : ;Xn�; N 2 No:

For every point P D .a1; : : : ;an/, the ring of germs of functions at P is

OP D fg=h 2 k.X1; : : : ;Xn/ j h.P /¤ 0g D kŒX1; : : : ;Xn�.X1�a1;:::;Xn�an/;

and its maximal ideal consists of those g=h with g.P /D 0:(b) Let U D f.a;b/ 2 k2 j .a;b/¤ .0;0/g. It is an open subset of k2, but it is not a basic

open subset, because its complement f.0;0/g has dimension 0, and therefore can’t be of theform V..f // (see 2.25). Since U DD.X/[D.Y /, the ring of regular functions on U is

OU .U /D kŒX;Y �X \kŒX;Y �Y

(intersection inside k.X;Y /). A regular function f on U can be expressed

f Dg.X;Y /

XNDh.X;Y /

YM;

3The terminology is similar to that of “meromorphic function”, which also are not functions on the wholespace.

60 3. AFFINE ALGEBRAIC VARIETIES

where we can assume X - g and Y - h. On multiplying through by XNYM , we find that

g.X;Y /YM D h.X;Y /XN :

Because X doesn’t divide the left hand side, it can’t divide the right hand side either, andso N D 0. Similarly, M D 0, and so f 2 kŒX;Y �: every regular function on U extendsuniquely to a regular function on k2.

Morphisms of ringed spaces

A morphism of ringed spaces .V;OV /! .W;OW / is a continuous map 'WV !W suchthat

f 2 � .U;OW / H) f ı' 2 � .'�1U;OV /

for all open subsetsU ofW . Sometimes we write '�.f / for f ı'. IfU is an open subset ofV , then the inclusion .U;OV jV / ,! .V;OV / is a morphism of ringed spaces. A morphismof ringed spaces is an isomorphism if it is bijective and its inverse is also a morphism ofringed spaces (in particular, it is a homeomorphism).

EXAMPLE 3.10. (a) Let V and V 0 be topological spaces endowed with their sheaves OVand OV 0 of continuous real valued functions. Every continuous map 'WV ! V 0 is a mor-phism of ringed structures .V;OV /! .V 0;OV 0/.

(b) Let U and U 0 be open subsets of Rn and Rm respectively, and let xi be the coordi-nate function .a1; : : : ;an/ 7! ai . Recall from advanced calculus that a map

'WU ! U 0 � Rm

is said to be smooth (infinitely differentiable) if each of its component functions 'i D xi ı'WU ! R has continuous partial derivatives of all orders, in which case f ı' is smoothfor all smooth f WU 0! R. Therefore, when U and U 0 are endowed with their sheaves ofsmooth functions, a continuous map 'WU ! U 0 is smooth if and only if it is a morphism ofringed spaces.

(c) Same as (b), but replace R with C and “smooth” with “analytic”.

REMARK 3.11. A morphism of ringed spaces maps germs of functions to germs of func-tions. More precisely, a morphism 'W.V;OV /! .V 0;OV 0/ induces a homomorphism

OV;P OV 0;'.P /;

for each P 2 V , namely, the homomorphism sending the germ represented by .f;U / to thegerm represented by .f ı';'�1.U //.

Affine algebraic varieties

We have just seen that every algebraic set V � kn gives rise to a ringed space .V;OV /. Aringed space isomorphic to one of this form is called an affine algebraic variety over k. Amap f WV !W of affine varieties is regular (or a morphism of affine algebraic varieties)if it is a morphism of ringed spaces. With these definitions, the affine algebraic varietiesbecome a category. Since we consider no nonalgebraic affine varieties, we shall sometimesdrop “algebraic”.

The category of affine algebraic varieties 61

In particular, every algebraic set has a natural structure of an affine variety. We usuallywrite An for kn regarded as an affine algebraic variety. Note that the affine varieties wehave constructed so far have all been embedded in An. I now explain how to construct“unembedded” affine varieties.

An affine k-algebra is defined to be a reduced finitely generated k-algebra. For suchan algebra A, there exist xi 2 A such that AD kŒx1; : : : ;xn�, and the kernel of the homo-morphism

Xi 7! xi WkŒX1; : : : ;Xn�! A

is a radical ideal. Therefore (2.13) implies that the intersection of the maximal ideals in Ais 0. Moreover, Zariski’s lemma 2.7 implies that, for every maximal ideal m� A, the mapk!A!A=m is an isomorphism. Thus we can identify A=m with k. For f 2A, we writef .m/ for the image of f in A=mD k, i.e., f .m/D f (mod m/.

We attach a ringed space .V;OV / to A by letting V be the set of maximal ideals in A.For f 2 A let

D.f /D fm j f .m/¤ 0g D fm j f …mg:

Since D.fg/DD.f /\D.g/, there is a topology on V for which the D.f / form a base.A pair of elements g;h 2 A, h¤ 0, gives rise to a function

m 7!g.m/

h.m/WD.h/! k;

and, for U an open subset of V , we define OV .U / to be any function f WU ! k that is ofthis form in a neighbourhood of each point of U .

PROPOSITION 3.12. The pair .V;OV / is an affine variety with � .V;OV /D A.

PROOF. Represent A as a quotient kŒX1; : : : ;Xn�=aD kŒx1; : : : ;xn�. Then .V;OV / is iso-morphic to the ringed space attached to V.a/ (see 3.8(a)). 2

We write spm.A/ for the topological space V , and Spm.A/ for the ringed space .V;OV /.

PROPOSITION 3.13. A ringed space .V;OV / is an affine variety if and only if � .V;OV /is an affine k-algebra and the canonical map V ! spm.� .V;OV // is an isomorphism ofringed spaces.

PROOF. Let .V;OV / be an affine variety, and let AD � .V;OV /. For every P 2 V , mPdefD

ff 2A j f .P /D 0g is a maximal ideal inA, and it is straightforward to check that P 7!mPis an isomorphism of ringed spaces. Conversely, if � .V;OV / is an affine k-algebra, thenthe proposition shows that Spm.� .V;OV // is an affine variety. 2

The category of affine algebraic varieties

For each affine k-algebra A, we have an affine variety Spm.A/, and conversely, for eachaffine variety .V;OV /, we have an affine k-algebra kŒV �D � .V;OV /. We now make thiscorrespondence into an equivalence of categories.

62 3. AFFINE ALGEBRAIC VARIETIES

Let ˛WA! B be a homomorphism of affine k-algebras. For every h 2 A, ˛.h/ isinvertible inB˛.h/, and so the homomorphismA!B!B˛.h/ extends to a homomorphism

g

hm7!

˛.g/

˛.h/mWAh! B˛.h/:

For every maximal ideal n of B , mD ˛�1.n/ is maximal in A because A=m!B=nD k isan injective map of k-algebras which implies that A=mD k. Thus ˛ defines a map

'WspmB! spmA; '.n/D ˛�1.n/Dm:

For mD ˛�1.n/D '.n/, we have a commutative diagram:

A˛

����! B??y ??yA=m

'����! B=n:

Recall that the image of an element f of A in A=m' k is denoted f .m/. Therefore, thecommutativity of the diagram means that, for f 2 A,

f .'.n//D ˛.f /.n/, i.e., f ı' D ˛: (*)

Since '�1D.f /DD.f ı'/ (obviously), it follows from (*) that

'�1.D.f //DD.˛.f //;

and so ' is continuous.Let f be a regular function on D.h/, and write f D g=hm, g 2 A. Then, from (*)

we see that f ı' is the function on D.˛.h// defined by ˛.g/=˛.h/m. In particular, it isregular, and so f 7! f ı' maps regular functions onD.h/ to regular functions onD.˛.h//.It follows that f 7! f ı' sends regular functions on any open subset of spm.A/ to regularfunctions on the inverse image of the open subset. Thus ˛ defines a morphism of ringedspaces Spm.B/! Spm.A/.

Conversely, by definition, a morphism of 'W.V;OV /! .W;OW / of affine algebraicvarieties defines a homomorphism of the associated affine k-algebras kŒW �! kŒV �. Sincethese maps are inverse, we have shown:

PROPOSITION 3.14. For any affine algebras A and B ,

Homk-alg.A;B/'!Mor.Spm.B/;Spm.A//I

for any affine varieties V and W ,

Mor.V;W /'! Homk-alg.kŒW �;kŒV �/:

In terms of categories, Proposition 3.14 can now be restated as:

PROPOSITION 3.15. The functorA 7! SpmA is a (contravariant) equivalence from the cat-egory of affine k-algebras to that of affine algebraic varieties with quasi-inverse .V;OV / 7!� .V;OV /.

Explicit description of morphisms of affine varieties 63

Explicit description of morphisms of affine varieties

PROPOSITION 3.16. Let V D V.a/ � km, W D V.b/ � kn. The following conditions ona continuous map 'WV !W are equivalent:

(a) ' is regular;(b) the components '1; : : : ;'m of ' are all regular;(c) f 2 kŒW � H) f ı' 2 kŒV �.

PROOF. (a) H) (b). By definition 'i D yi ı' where yi is the coordinate function

.b1; : : : ;bn/ 7! bi WW ! k:

Hence this implication follows directly from the definition of a regular map.(b) H) (c). The map f 7! f ı' is a k-algebra homomorphism from the ring of all

functions W ! k to the ring of all functions V ! k, and (b) says that the map sends thecoordinate functions yi on W into kŒV �. Since the yi ’s generate kŒW � as a k-algebra, thisimplies that it sends kŒW � into kŒV �.

(c) H) (a). The map f 7! f ı' is a homomorphism ˛WkŒW �! kŒV �. It thereforedefines a map spmkŒV �! spmkŒW �, and it remains to show that this coincides with 'when we identify spmkŒV � with V and spmkŒW � with W . Let P 2 V , let Q D '.P /,and let mP and mQ be the ideals of elements of kŒV � and kŒW � that are zero at P and Qrespectively. Then, for f 2 kŒW �,

˛.f / 2mP ” f .'.P //D 0 ” f .Q/D 0 ” f 2mQ:

Therefore ˛�1.mP /DmQ, which is what we needed to show. 2

REMARK 3.17. For P 2 V , the maximal ideal in OV;P consists of the germs representedby pairs .f;U / with f .P /D 0. Clearly therefore, the map OW ;'.P /!OV;P defined by '(see 3.11) maps m'.P / into mP , i.e., it is a local homomorphism of local rings.

Now consider equations

Y1 D f1.X1; : : : ;Xm/

: : :

Yn D fn.X1; : : : ;Xm/:

On the one hand, they define a regular map 'Wkm! kn, namely,

.a1; : : : ;am/ 7! .f1.a1; : : : ;am/; : : : ;fn.a1; : : : ;am//:

On the other hand, they define a homomorphism ˛WkŒY1; : : : ;Yn�! kŒX1; : : : ;Xn� of k-algebras, namely, that sending

Yi 7! fi .X1; : : : ;Xn/:

This map coincides with g 7! g ı', because

˛.g/.P /D g.: : : ;fi .P /; : : :/D g.'.P //:

64 3. AFFINE ALGEBRAIC VARIETIES

Now consider closed subsets V.a/� km and V.b/� kn with a and b radical ideals. I claimthat ' maps V.a/ into V.b/ if and only if ˛.b/� a. Indeed, suppose '.V.a//� V.b/, andlet g 2 b; for Q 2 V.b/,

˛.g/.Q/D g.'.Q//D 0;

and so ˛.f / 2 IV.b/D b. Conversely, suppose ˛.b/� a, and let P 2 V.a/; for f 2 a,

f .'.P //D ˛.f /.P /D 0;

and so '.P / 2 V.a/. When these conditions hold, ' is the morphism of affine varietiesV.a/! V.b/ corresponding to the homomorphism kŒY1; : : : ;Ym�=b! kŒX1; : : : ;Xn�=a de-fined by ˛.

Thus, we see that the regular maps

V.a/! V.b/

are all of the form

P 7! .f1.P /; : : : ;fm.P //; fi 2 kŒX1; : : : ;Xn�:

In particular, they all extend to regular maps An! Am.

EXAMPLE 3.18. (a) Consider a k-algebraR. From a k-algebra homomorphism ˛WkŒX�!

R, we obtain an element ˛.X/ 2 R, and ˛.X/ determines ˛ completely. Moreover, ˛.X/can be any element of R. Thus

˛ 7! ˛.X/WHomk�alg.kŒX�;R/'�!R:

According to (3.14)Mor.V;A1/D Homk-alg.kŒX�;kŒV �/:

Thus the regular maps V ! A1 are simply the regular functions on V (as we would hope).(b) Define A0 to be the ringed space .V0;OV0/ with V0 consisting of a single point, and

� .V0;OV0/D k. Equivalently, A0 D Spmk. Then, for any affine variety V ,

Mor.A0;V /' Homk-alg.kŒV �;k/' V

where the last map sends ˛ to the point corresponding to the maximal ideal Ker.˛/.(c) Consider t 7! .t2; t3/WA1! A2. This is bijective onto its image,

V W Y 2 DX3;

but it is not an isomorphism onto its image – the inverse map is not regular. Because of(3.15), it suffices to show that t 7! .t2; t3/ doesn’t induce an isomorphism on the rings ofregular functions. We have kŒA1�D kŒT � and kŒV �D kŒX;Y �=.Y 2�X3/D kŒx;y�. Themap on rings is

x 7! T 2; y 7! T 3; kŒx;y�! kŒT �;

which is injective, but its image is kŒT 2;T 3�¤ kŒT �. In fact, kŒx;y� is not integrally closed:.y=x/2�xD 0, and so .y=x/ is integral over kŒx;y�, but y=x … kŒx;y� (it maps to T underthe inclusion k.x;y/ ,! k.T //:

Subvarieties 65

(d) Let k have characteristic p¤ 0, and consider x 7! xpWAn!An. This is a bijection,but it is not an isomorphism because the corresponding map on rings,

Xi 7!Xpi WkŒX1; : : : ;Xn�! kŒX1; : : : ;Xn�;

is not surjective.This is the famous Frobenius map. Take k to be the algebraic closure of Fp, and write

F for the map. Recall that for each m � 1 there is a unique subfield Fpm of k of degree mover Fp, and that its elements are the solutions ofXp

m

DX (FT 4.20). Therefore, the fixedpoints of Fm are precisely the points of An with coordinates in Fpm . Let f .X1; : : : ;Xn/ bea polynomial with coefficients in Fpm , say,

f DX

ci1���inXi11 � � �X

inn ; ci1���in 2 Fpm :

Let f .a1; : : : ;an/D 0. Then

0D�X

c˛ai11 � � �a

inn

�pmD

Xc˛a

pmi11 � � �ap

minn ;

and so f .apm

1 ; : : : ;apm

n /D 0. Here we have used that the binomial theorem takes the simpleform .XCY /p

m

D Xpm

CY pm

in characteristic p. Thus Fm maps V.f / into itself, andits fixed points are the solutions of

f .X1; : : : ;Xn/D 0

in Fpm .In one of the most beautiful pieces of mathematics of the second half of the twentieth

century, Grothendieck defined a cohomology theory (etale cohomology) and proved a fixedpoint formula that allowed him to express the number of solutions of a system of polynomialequations with coordinates in Fpn as an alternating sum of traces of operators on finite-dimensional vector spaces, and Deligne used this to obtain very precise estimates for thenumber of solutions. See my course notes: Lectures on Etale Cohomology.

Subvarieties

Let A be an affine k-algebra. For any ideal a in A, we define

V.a/D fP 2 spm.A/ j f .P /D 0 all f 2 ag

D fm maximal ideal in A j a�mg:

This is a closed subset of spm.A/, and every closed subset is of this form.Now assume a is radical, so that A=a is again reduced. Corresponding to the homomor-

phism A! A=a, we get a regular map

Spm.A=a/! Spm.A/

The image is V.a/, and spm.A=a/! V.a/ is a homeomorphism. Thus every closed subsetof spm.A/ has a natural ringed structure making it into an affine algebraic variety. We callV.a/ with this structure a closed subvariety of V:

66 3. AFFINE ALGEBRAIC VARIETIES

ASIDE 3.19. If .V;OV / is a ringed space, and Z is a closed subset of V , we can definea ringed space structure on Z as follows: let U be an open subset of Z, and let f bea function U ! k; then f 2 � .U;OZ/ if for each P 2 U there is a germ .U 0;f 0/ of afunction at P (regarded as a point of V / such that f 0jZ \U 0 D f . One can check thatwhen this construction is applied to Z D V.a/, the ringed space structure obtained is thatdescribed above.

PROPOSITION 3.20. Let .V;OV / be an affine variety and let h be a nonzero element ofkŒV �. Then

.D.h/;OV jD.h//' Spm.Ah/I

in particular, it is an affine variety.

PROOF. The map A! Ah defines a morphism spm.Ah/! spm.A/. The image is D.h/,and it is routine (using (1.29)) to verify the rest of the statement. 2

If V D V.a/� kn, then

.a1; : : : ;an/ 7! .a1; : : : ;an;h.a1; : : : ;an/�1/WD.h/! knC1;

defines an isomorphism of D.h/ onto V.a;1�hXnC1/. For example, there is an isomor-phism of affine varieties

a 7! .a;1=a/WA1r f0g ! V � A2;

where V is the subvariety XY D 1 of A2 — the reader should draw a picture.

REMARK 3.21. We have seen that all closed subsets and all basic open subsets of an affinevariety V are again affine varieties with their natural ringed structure, but this is not truefor all open subsets U . As we saw in (3.13), if U is affine, then the natural map U !spm� .U;OU / is a bijection. But for U D A2r .0;0/ D D.X/[D.Y /, we know that� .U;OA2/D kŒX;Y � (see 3.9b), but U ! spmkŒX;Y � is not a bijection, because the ideal.X;Y / is not in the image. However, U is clearly a union of affine algebraic varieties —we shall see in the next chapter that it is a (nonaffine) algebraic variety.

Properties of the regular map defined by specm.˛/

PROPOSITION 3.22. Let ˛WA! B be a homomorphism of affine k-algebras, and let

'WSpm.B/! Spm.A/

be the corresponding morphism of affine varieties (so that ˛.f /D ' ıf /.

(a) The image of ' is dense for the Zariski topology if and only if ˛ is injective.(b) ' defines an isomorphism of Spm.B/ onto a closed subvariety of Spm.A/ if and only

if ˛ is surjective.

Affine space without coordinates 67

PROOF. (a) Let f 2 A. If the image of ' is dense, then

f ı' D 0 H) f D 0:

On the other hand, if the image of ' is not dense, then the closure of its image will be aproper closed subset of Spm.A/, and so there will be a nonzero function f 2 A that is zeroon it. Then f ı' D 0.

(b) If ˛ is surjective, then it defines an isomorphism A=a! B where a is the kernel of˛. This induces an isomorphism of Spm.B/ with its image in Spm.A/. 2

A regular map 'WV ! W of affine algebraic varieties is said to be a dominant (ordominating) if its image is dense in W . The proposition then says that:

' is dominant ” f 7! f ı'W� .W;OW /! � .V;OV / is injective.

Affine space without coordinates

Let E be a vector space over k of dimension n. The set A.E/ of points of E has a naturalstructure of an algebraic variety: the choice of a basis for E defines an bijection A.E/!An, and the inherited structure of an affine algebraic variety on A.E/ is independent ofthe choice of the basis (because the bijections defined by two different bases differ by anautomorphism of An).

We now give an intrinsic definition of the affine variety A.E/. Let V be a finite-dimensional vector space over a field k (not necessarily algebraically closed). The tensoralgebra of V is

T �V DMi�0

V ˝i

with multiplication defined by

.v1˝�� �˝vi / � .v01˝�� �˝v

0j /D v1˝�� �˝vi ˝v

01˝�� �˝v

0j :

It is noncommutative k-algebra, and the choice of a basis e1; : : : ; en for V defines an isomor-phism to T �V from the k-algebra of noncommuting polynomials in the symbols e1; : : : ; en.The symmetric algebra S�.V / of V is defined to be the quotient of T �V by the two-sidedideal generated by the relations

v˝w�w˝v; v;w 2 V:

This algebra is generated as a k-algebra by commuting elements (namely, the elementsof V D V ˝1), and so is commutative. The choice of a basis e1; : : : ; en for V defines anisomorphism of k-algebras

e1 � � �ei 7! e1˝�� �˝ ei WkŒe1; : : : ; en�! S�.V /

(here kŒe1; : : : ; en� is the commutative polynomial ring in the symbols e1; : : : ; en). In partic-ular, S�.V / is an affine k-algebra. The pair .S�.V /; i/ consisting of S�.V / and the natural

68 3. AFFINE ALGEBRAIC VARIETIES

k-linear map i WV ! S�.V / has the following universal property: any k-linear map V !A

from V into a k-algebra A extends uniquely to a k-algebra homomorphism S�.V /! A:

V S�.V /

A:

i

k-linear 9Š k-algebra (8)

As usual, this universal property determines the pair .S�.V /; i/ uniquely up to a uniqueisomorphism.

We now define A.E/ to be Spm.S�.E_//. For an affine k-algebra A,

Mor.Spm.A/;A.E//' Homk-algebra.S�.E_/;A/ .3:14/

' Homk-linear.E_;A/ .8/

'E˝k A .linear algebra/:

In particular,A.E/.k/'E:

Moreover, the choice of a basis e1; : : : ; en for E determines a (dual) basis f1; : : : ;fn of E_,and hence an isomorphism of k-algebras kŒf1; : : : ;fn�! S�.E_/. The map of algebraicvarieties defined by this homomorphism is the isomorphism

A.E/! An

whose map on the underlying sets is the isomorphism E! kn defined by the basis of E.

NOTES. We have associated with any affine k-algebra A an affine variety whose underlying topo-logical space is the set of maximal ideals in A. It may seem strange to be describing a topologicalspace in terms of maximal ideals in a ring, but the analysts have been doing this for more than 60years. Gel’fand and Kolmogorov in 19394 proved that if S and T are compact topological spaces,and the rings of real-valued continuous functions on S and T are isomorphic (just as rings), then Sand T are homeomorphic. The proof begins by showing that, for such a space S , the map

P 7!mPdefD ff WS ! R j f .P /D 0g

is one-to-one correspondence between the points in the space and maximal ideals in the ring.

Exercises

3-1. Show that a map between affine varieties can be continuous for the Zariski topologywithout being regular.

3-2. Let q be a power of a prime p, and let Fq be the field with q elements. Let S be asubset of FqŒX1; : : : ;Xn�, and let V be its zero set in kn, where k is the algebraic closureof Fq . Show that the map .a1; : : : ;an/ 7! .a

q1 ; : : : ;a

qn/ is a regular map 'WV ! V (i.e.,

'.V / � V ). Verify that the set of fixed points of ' is the set of zeros of the elements of Swith coordinates in Fq . (This statement enables one to study the cardinality of the last setusing a Lefschetz fixed point formula — see my lecture notes on etale cohomology.)

4On rings of continuous functions on topological spaces, Doklady 22, 11-15. See also Allen Shields,Banach Algebras, 1939–1989, Math. Intelligencer, Vol 11, no. 3, p15.

Exercises 69

3-3. Find the image of the regular map

.x;y/ 7! .x;xy/WA2! A2

and verify that it is neither open nor closed.

3-4. Show that the circleX2CY 2D 1 is isomorphic (as an affine variety) to the hyperbolaXY D 1, but that neither is isomorphic to A1.

3-5. Let C be the curve Y 2 DX2CX3, and let ' be the regular map

t 7! .t2�1; t.t2�1//WA1! C:

Is ' an isomorphism?

CHAPTER 4Algebraic Varieties

An algebraic variety is a ringed space that is locally isomorphic to an affine algebraic va-riety, just as a topological manifold is a ringed space that is locally isomorphic to an opensubset of Rn; both are required to satisfy a separation axiom. Throughout this chapter, k isalgebraically closed.

Algebraic prevarieties

As motivation, recall the following definitions.

DEFINITION 4.1. (a) A topological manifold of dimension n is a ringed space .V;OV /such that V is Hausdorff and every point of V has an open neighbourhood U for which.U;OV jU/ is isomorphic to the ringed space of continuous functions on an open subset ofRn (cf. 3.2a)).

(b) A differentiable manifold of dimension n is a ringed space such that V is Hausdorffand every point of V has an open neighbourhood U for which .U;OV jU/ is isomorphic tothe ringed space of smooth functions on an open subset of Rn (cf. 3.2b).

(c) A complex manifold of dimension n is a ringed space such that V is Hausdorff andevery point of V has an open neighbourhood U for which .U;OV jU/ is isomorphic to theringed space holomorphic functions on an open subset of Cn (cf. 3.2c).

These definitions are easily seen to be equivalent to the more classical definitions interms of charts and atlases.1 Often one imposes additional conditions on V , for example,that it be connected or that it have a countable base of open subsets.

DEFINITION 4.2. An algebraic prevariety over k is a ringed space .V;OV / such that V isquasicompact and every point of V has an open neighbourhood U for which .U;OV jU/ isan affine algebraic variety over k.

Thus, a ringed space .V;OV / is an algebraic prevariety over k if there exists a finiteopen covering V D

SVi such that .Vi ;OV jVi / is an affine algebraic variety over k for all

i . An algebraic variety will be defined to be an algebraic prevariety satisfying a certainseparation condition.

1Provided the latter are stated correctly, which is frequently not the case.

71

72 4. ALGEBRAIC VARIETIES

An open subset U of an algebraic prevariety V such that .U , OV jU/ is an affine alge-braic variety is called an open affine (subvariety) in V . Because V is a finite union of openaffines, and in each open affine the open affines (in fact the basic open subsets) form a basefor the topology, it follows that the open affines form a base for the topology on V .

Let .V;OV / be an algebraic prevariety, and let U be an open subset of V . The functionsf WU ! k lying in � .U;OV / are called regular. Note that if .Ui / is an open covering of Vby affine varieties, then f WU ! k is regular if and only if f jUi \U is regular for all i (by3.1(c)). Thus understanding the regular functions on open subsets of V amounts to under-standing the regular functions on the open affine subvarieties and how these subvarieties fittogether to form V .

EXAMPLE 4.3. (Projective space). Let Pn denote knC1r forigingmodulo the equivalencerelation

.a0; : : : ;an/� .b0; : : : ;bn/ ” .a0; : : : ;an/D .cb0; : : : ; cbn/ some c 2 k�:

Thus the equivalence classes are the lines through the origin in knC1 (with the origin omit-ted). Write .a0W : : : W an/ for the equivalence class containing .a0; : : : ;an/. For each i , let

Ui D f.a0 W : : : W ai W : : : W an/ 2 Pn j ai ¤ 0g:

Then Pn DSUi , and the map

.a0W : : : Wan/ 7! .a0=ai ; : : : ;an=ai / WUiui�! An

(the term ai=ai is omitted) is a bijection. In Chapter 6 we shall show that there is a uniquestructure of a (separated) algebraic variety on Pn for which each Ui is an open affine sub-variety of Pn and each map ui is an isomorphism of algebraic varieties.

Regular maps

In each of the examples (4.1a,b,c), a morphism of manifolds (continuous map, smoothmap, holomorphic map respectively) is just a morphism of ringed spaces. This motivatesthe following definition.

Let .V;OV / and .W;OW / be algebraic prevarieties. A map 'WV ! W is said to beregular if it is a morphism of ringed spaces. A composite of regular maps is again regular(this is a general fact about morphisms of ringed spaces).

Note that we have three categories:

(affine varieties)� (algebraic prevarieties)� (ringed spaces).

Each subcategory is full, i.e., the morphisms Mor.V;W / are the same in the three categories.

PROPOSITION 4.4. Let .V;OV / and .W;OW / be prevarieties, and let 'WV !W be a con-tinuous map (of topological spaces). Let W D

SWj be a covering of W by open affines,

and let '�1.Wj /DSVj i be a covering of '�1.Wj / by open affines. Then ' is regular if

and only if its restrictions'jVj i WVj i !Wj

are regular for all i;j .

Algebraic varieties 73

PROOF. We assume that ' satisfies this condition, and prove that it is regular. Let f bea regular function on an open subset U of W . Then f jU \Wj is regular for each Wj(sheaf condition 3.1(b)), and so f ı 'j'�1.U /\ Vj i is regular for each j; i (this is ourassumption). It follows that f ı' is regular on '�1.U / (sheaf condition 3.1(c)). Thus ' isregular. The converse is even easier. 2

ASIDE 4.5. A differentiable manifold of dimension n is locally isomorphic to an opensubset of Rn. In particular, all manifolds of the same dimension are locally isomorphic.This is not true for algebraic varieties, for two reasons:

(a) We are not assuming our varieties are nonsingular (see Chapter 5 below).(b) The inverse function theorem fails in our context. If P is a nonsingular point on

variety of dimension d , we shall see (in the next chapter) that there does exist a neighbour-hood U of P and a regular map 'WU ! Ad such that map .d'/P WTP ! T'.P / on thetangent spaces is an isomorphism, but also that there does not always exist a U for which 'itself is an isomorphism onto its image (as the inverse function theorem would assert).

Algebraic varieties

In the study of topological manifolds, the Hausdorff condition eliminates such bizarre pos-sibilities as the line with the origin doubled (see 4.10 below) where a sequence tending tothe origin has two limits.

It is not immediately obvious how to impose a separation axiom on our algebraic va-rieties, because even affine algebraic varieties are not Hausdorff. The key is to restate theHausdorff condition. Intuitively, the significance of this condition is that it prevents a se-quence in the space having more than one limit. Thus a continuous map into the spaceshould be determined by its values on a dense subset, i.e., if '1 and '2 are continuousmaps Z! U that agree on a dense subset of Z then they should agree on the whole of Z.Equivalently, the set where two continuous maps '1;'2WZ ⇒ U agree should be closed.Surprisingly, affine varieties have this property, provided '1 and '2 are required to be reg-ular maps.

LEMMA 4.6. Let '1 and '2 be regular maps of affine algebraic varieties Z ⇒ V . Thesubset of Z on which '1 and '2 agree is closed.

PROOF. There are regular functions xi on V such that P 7! .x1.P /; : : : ;xn.P // identifiesV with a closed subset ofAn (take the xi to be any set of generators for kŒV � as a k-algebra).Now xi ı'1 and xi ı'2 are regular functions on Z, and the set where '1 and '2 agree isTniD1V.xi ı'1�xi ı'2/, which is closed. 2

DEFINITION 4.7. An algebraic prevariety V is said to be separated, or to be an algebraicvariety, if it satisfies the following additional condition:

Separation axiom: for every pair of regular maps '1;'2WZ ⇒ V with Z anaffine algebraic variety, the set fz 2Z j '1.z/D '2.z/g is closed in Z.

The terminology is not completely standardized: some authors require a variety to beirreducible, and some call a prevariety a variety.2

2Our terminology is agrees with that of J-P. Serre, Faisceaux algebriques coherents. Ann. of Math. 61,(1955). 197–278.

74 4. ALGEBRAIC VARIETIES

PROPOSITION 4.8. Let '1 and '2 be regular maps Z⇒ V from an algebraic prevariety Zto a separated prevariety V . The subset of Z on which '1 and '2 agree is closed.

PROOF. Let W be the set on which '1 and '2 agree. For any open affine U of Z, W \Uis the subset of U on which '1jU and '2jU agree, and so W \U is closed. This impliesthat W is closed because Z is a finite union of open affines. 2

EXAMPLE 4.9. The open subspace U D A2r f.0;0/g of A2 becomes an algebraic varietywhen endowed with the sheaf OA2 jU (cf. 3.21).

EXAMPLE 4.10. (The affine line with the origin doubled.) Let V1 and V2 be copies of A1.Let V � D V1tV2 (disjoint union), and give it the obvious topology. Define an equivalencerelation on V � by

x (in V1/� y (in V2/ ” x D y and x ¤ 0:

Let V be the quotient space V D V �=� with the quotient topology (a set is open if and onlyif its inverse image in V � is open). Then V1 and V2 are open subspaces of V , V D V1[V2,and V1\V2 D A1�f0g. Define a function on an open subset to be regular if its restrictionto each Vi is regular. This makes V into a prevariety, but not a variety: it fails the separationaxiom because the two maps

A1 D V1 ,! V �; A1 D V2 ,! V �

agree exactly on A1�f0g, which is not closed in A1.

Let Vark denote the category of algebraic varieties over k and regular maps. The functorA 7! SpmA is a fully faithful contravariant functor Affk!Vark , and defines an equivalenceof the first category with the subcategory of the second whose objects are the affine algebraicvarieties.

Maps from varieties to affine varieties

Let .V;OV / be an algebraic variety, and let ˛WA! � .V;OV / be a homomorphism froman affine k-algebra A to the k-algebra of regular functions on V . For any P 2 V , f 7!˛.f /.P / is a k-algebra homomorphism A! k, and so its kernel '.P / is a maximal idealin A. In this way, we get a map

'WV ! spm.A/

which is easily seen to be regular. Conversely, from a regular map 'WV ! Spm.A/, we geta k-algebra homomorphism f 7! f ı'WA! � .V;OV /. Since these maps are inverse, wehave proved the following result.

PROPOSITION 4.11. For an algebraic variety V and an affine k-algebraA, there is a canon-ical one-to-one correspondence

Mor.V;Spm.A//' Homk-algebra.A;� .V;OV //:

Subvarieties 75

Let V be an algebraic variety such that � .V;OV / is an affine k-algebra. Then propo-sition shows that the regular map 'WV ! Spm.� .V;OV // defined by id� .V;OV / has thefollowing universal property: any regular map from V to an affine algebraic variety Ufactors uniquely through ':

V Spm.� .V;OV //

U:

'

9Š

Subvarieties

Let .V;OV / be a ringed space, and let W be a subspace. For U open in W , define OW .U /to be the set of functions f WU ! k such that there exist open subsets Ui of V and fi 2OV .Ui / such that U DW \ .

SUi / and f jW \Ui D fi jW \Ui for all i . Then .W;OW /

is again a ringed space.We now let .V;OV / be a prevariety, and examine when .W;OW / is also a prevariety.

Open subprevarieties. Because the open affines form a base for the topology on V , forany open subset U of V , .U;OV jU/ is a prevariety. The inclusion U ,! V is regular, andU is called an open subprevariety of V . A regular map 'WW ! V is an open immersionif '.W / is open in V and ' defines an isomorphism W ! '.W / (of prevarieties).

Closed subprevarieties. Any closed subset Z in V has a canonical structure of an al-gebraic prevariety: endow it with the induced topology, and say that a function f on anopen subset of Z is regular if each point P in the open subset has an open neighbourhoodU in V such that f extends to a regular function on U . To show that Z, with this ringedspace structure is a prevariety, check that for every open affine U � V , the ringed space.U \Z;OZ jU \Z/ is isomorphic to U \Z with its ringed space structure acquired as aclosed subset of U (see p66). Such a pair .Z;OZ/ is called a closed subprevariety of V .A regular map 'WW ! V is a closed immersion if '.W / is closed in V and ' defines anisomorphism W ! '.W / (of prevarieties).

Subprevarieties. A subset W of a topological space V is said to be locally closed ifevery point P in W has an open neighbourhood U in V such that W \U is closed in U .Equivalent conditions: W is the intersection of an open and a closed subset of V ; W isopen in its closure. A locally closed subsetW of a prevariety V acquires a natural structureas a prevariety: write it as the intersection W D U \Z of an open and a closed subset; Zis a prevariety, and W (being open in Z/ therefore acquires the structure of a prevariety.This structure on W has the following characterization: the inclusion map W ,! V isregular, and a map 'WV 0 ! W with V 0 a prevariety is regular if and only if it is regularwhen regarded as a map into V . With this structure, W is called a sub(pre)variety of V .A morphism 'WV 0! V is called an immersion if it induces an isomorphism of V 0 ontoa subvariety of V . Every immersion is the composite of an open immersion with a closedimmersion (in both orders).

A subprevariety of a variety is automatically separated.

76 4. ALGEBRAIC VARIETIES

Application.

PROPOSITION 4.12. A prevariety V is separated if and only if two regular maps from aprevariety to V agree on the whole prevariety whenever they agree on a dense subset of it.

PROOF. If V is separated, then the set on which a pair of regular maps '1;'2WZ⇒ V agreeis closed, and so must be the whole of the Z.

Conversely, consider a pair of maps '1;'2WZ ⇒ V , and let S be the subset of Z onwhich they agree. We assume V has the property in the statement of the proposition, andshow that S is closed. Let NS be the closure of S in Z. According to the above discussion,NS has the structure of a closed prevariety of Z and the maps '1j NS and '2j NS are regular.

Because they agree on a dense subset of NS they agree on the whole of NS , and so S D NS isclosed. 2

Prevarieties obtained by patching

PROPOSITION 4.13. Let V DSi2I Vi (finite union), and suppose that each Vi has the

structure of a ringed space. Assume the following “patching” condition holds:for all i;j , Vi \Vj is open in both Vi and Vj and OVi jVi \Vj DOVj jVi \Vj .

Then there is a unique structure of a ringed space on V for which

(a) each inclusion Vi ,! V is a homeomorphism of Vi onto an open set, and(b) for each i 2 I , OV jVi DOVi .

If every Vi is an algebraic prevariety, then so also is V , and to give a regular map fromV to a prevariety W amounts to giving a family of regular maps 'i WVi ! W such that'i jVi \Vj D 'j jVi \Vj :

PROOF. One checks easily that the subsets U � V such that U \Vi is open for all i are theopen subsets for a topology on V satisfying (a), and that this is the only topology to satisfy(a). Define OV .U / to be the set of functions f WU ! k such that f jU \Vi 2OVi .U \Vi /for all i . Again, one checks easily that OV is a sheaf of k-algebras satisfying (b), and thatit is the only such sheaf.

For the final statement, if each .Vi ;OVi / is a finite union of open affines, so also is.V;OV /. Moreover, to give a map 'WV !W amounts to giving a family of maps 'i WVi !W such that 'i jVi \ Vj D 'j jVi \ Vj (obviously), and ' is regular if and only 'jVi isregular for each i . 2

Clearly, the Vi may be separated without V being separated (see, for example, 4.10).In (4.27) below, we give a condition on an open affine covering of a prevariety sufficient toensure that the prevariety is separated.

Products of varieties

Let V and W be objects in a category C. A triple

.V �W; pWV �W ! V; qWV �W !W /

Products of varieties 77

is said to be the product of V and W if it has the following universal property: for everypair of morphisms Z ! V , Z ! W in C, there exists a unique morphism Z ! V �W

making the diagram

Z

V V �W Wp q

9Š

commute. In other words, it is a product if the map

' 7! .p ı';q ı'/WHom.Z;V �W /! Hom.Z;V /�Hom.Z;W /

is a bijection. The product, if it exists, is uniquely determined up to a unique isomorphismby this universal property.

For example, the product of two sets (in the category of sets) is the usual cartesionproduct of the sets, and the product of two topological spaces (in the category of topologicalspaces) is the cartesian product of the spaces (as sets) endowed with the product topology.

We shall show that products exist in the category of algebraic varieties. Suppose, forthe moment, that V �W exists. For any prevariety Z, Mor.A0;Z/ is the underlying set ofZ; more precisely, for any z 2 Z, the map A0! Z with image z is regular, and these areall the regular maps (cf. 3.18b). Thus, from the definition of products we have

(underlying set of V �W /'Mor.A0;V �W /'Mor.A0;V /�Mor.A0;W /' (underlying set of V /� (underlying set of W /:

Hence, our problem can be restated as follows: given two prevarieties V and W , define onthe set V �W the structure of a prevariety such that

(a) the projection maps p;qWV �W ⇒ V;W are regular, and(b) a map 'WT ! V �W of sets (with T an algebraic prevariety) is regular if its compo-

nents p ı';q ı' are regular.

Clearly, there can be at most one such structure on the set V �W (because the identity mapwill identify any two structures having these properties).

Products of affine varieties

EXAMPLE 4.14. Let a and b be ideals in kŒX1; : : : ;Xm� and kŒXmC1; : : : ;XmCn� respec-tively, and let .a;b/ be the ideal in kŒX1; : : : ;XmCn� generated by the elements of a and b.Then there is an isomorphism

f ˝g 7! fgWkŒX1; : : : ;Xm�

a˝k

kŒXmC1; : : : ;XmCn�

b!kŒX1; : : : ;XmCn�

.a;b/:

Again this comes down to checking that the natural map from

Homk-alg.kŒX1; : : : ;XmCn�=.a;b/;R/

toHomk-alg.kŒX1; : : : ;Xm�=a;R/�Homk-alg.kŒXmC1; : : : ;XmCn�=b;R/

78 4. ALGEBRAIC VARIETIES

is a bijection. But the three sets are respectivelyV.a;b/D zero-set of .a;b/ in RmCn;V .a/D zero-set of a in Rm;V .b/D zero-set of b in Rn;

and so this is obvious.

The tensor product of two k-algebrasA andB has the universal property to be a productin the category of k-algebras, but with the arrows reversed. Because of the category anti-equivalence (3.15), this shows that Spm.A˝k B/ will be the product of SpmA and SpmBin the category of affine algebraic varieties once we have shown that A˝k B is an affinek-algebra.

PROPOSITION 4.15. Let A and B be k-algebras with A finitely generated.

(a) If A and B are reduced, then so also is A˝k B .(b) If A and B are integral domains, then so also is A˝k B .

PROOF. Let ˛ 2 A˝k B . Then ˛ DPniD1ai ˝bi , some ai 2 A, bi 2 B . If one of the bi ’s

is a linear combination of the remaining b’s, say, bn DPn�1iD1 cibi , ci 2 k, then, using the

bilinearity of˝, we find that

˛ D

n�1XiD1

ai ˝bi C

n�1XiD1

cian˝bi D

n�1XiD1

.ai C cian/˝bi :

Thus we can suppose that in the original expression of ˛, the bi ’s are linearly independentover k.

Now assume A and B to be reduced, and suppose that ˛ is nilpotent. Let m be amaximal ideal of A. From a 7! NaWA! A=mD k we obtain homomorphisms

a˝b 7! Na˝b 7! NabWA˝k B! k˝k B'! B

The imagePNaibi of ˛ under this homomorphism is a nilpotent element of B , and hence

is zero (because B is reduced). As the bi ’s are linearly independent over k, this means thatthe Nai are all zero. Thus, the ai ’s lie in all maximal ideals m of A, and so are zero (see2.13). Hence ˛ D 0, and we have shown that A˝k B is reduced.

Now assume that A and B are integral domains, and let ˛, ˛0 2 A˝k B be suchthat ˛˛0 D 0. As before, we can write ˛ D

Pai ˝ bi and ˛0 D

Pa0i ˝ b

0i with the sets

fb1;b2; : : :g and fb01;b02; : : :g each linearly independent over k. For each maximal ideal m

of A, we know .PNaibi /.

PNa0ib0i /D 0 in B , and so either .

PNaibi /D 0 or .

PNa0ib0i /D 0.

Thus either all the ai 2m or all the a0i 2m. This shows that

spm.A/D V.a1; : : : ;am/[V.a01; : : : ;a0n/:

As spm.A/ is irreducible (see 2.19), it follows that spm.A/ equals either V.a1; : : : ;am/ orV.a01; : : : ;a

0n/. In the first case ˛ D 0, and in the second ˛0 D 0. 2

EXAMPLE 4.16. We give some examples to illustrate that k must be taken to be alge-braically closed in the proposition.

Products of varieties 79

(a) Suppose k is nonperfect of characteristic p, so that there exists an element ˛ in analgebraic closure of k such that ˛ … k but ˛p 2 k. Let k0 D kŒ˛�, and let ˛p D a. Then.˛˝1�1˝˛/¤ 0 in k0˝k k0 (in fact, the elements ˛i˝˛j , 0� i;j � p�1, form a basisfor k0˝k k0 as a k-vector space), but

.˛˝1�1˝˛/p D .a˝1�1˝a/

D .1˝a�1˝a/ .because a 2 k/

D 0:

Thus k0˝k k0 is not reduced, even though k0 is a field.(b) Let K be a finite separable extension of k and let ˝ be a second field containing k.

By the primitive element theorem (FT 5.1),

K D kŒ˛�D kŒX�=.f .X//;

for some ˛ 2K and its minimal polynomial f .X/. Assume that ˝ is large enough to splitf , say, f .X/D

Qi X �˛i with ˛i 2˝. BecauseK=k is separable, the ˛i are distinct, and

so

˝˝kK '˝ŒX�=.f .X// (1.35(b))

'

Y˝ŒX�=.X �˛i / (1.1)

and so it is not an integral domain. For example,

C˝RC' CŒX�=.X � i/�CŒX�=.XC i/' C�C:

The proposition allows us to make the following definition.

DEFINITION 4.17. The product of the affine varieties V and W is

.V �W;OV�W /D Spm.kŒV �˝k kŒW �/

with the projection maps p;qWV �W ! V;W defined by the homomorphisms f 7! f ˝

1WkŒV �! kŒV �˝k kŒW � and g 7! 1˝gWkŒW �! kŒV �˝k kŒW �.

PROPOSITION 4.18. Let V and W be affine varieties.

(a) The variety .V �W;OV�W / is the product of .V;OV / and .W;OW / in the categoryof affine algebraic varieties; in particular, the set V �W is the product of the sets Vand W and p and q are the projection maps.

(b) If V and W are irreducible, then so also is V �W .

PROOF. (a) As noted at the start of the subsection, the first statement follows from (4.15a),and the second statement then follows by the argument on p77.

(b) This follows from (4.15b) and (2.19). 2

COROLLARY 4.19. Let V and W be affine varieties. For any prevariety T , a map 'WT !V �W is regular if p ı' and q ı' are regular.

80 4. ALGEBRAIC VARIETIES

PROOF. If p ı' and q ı' are regular, then (4.18) implies that ' is regular when restrictedto any open affine of T , which implies that it is regular on T . 2

The corollary shows that V �W is the product of V and W in the category of prevari-eties (hence also in the categories of varieties).

EXAMPLE 4.20. (a) It follows from (1.34) that AmCn endowed with the projection maps

Amp AmCn

q! An;

�p.a1; : : : ;amCn/D .a1; : : : ;am/

q.a1; : : : ;amCn/D .amC1; : : : ;amCn/;

is the product of Am and An.(b) It follows from (1.35c) that

V.a/p V.a;b/

q! V.b/

is the product of V.a/ and V.b/.

� The topology on V �W is not the product topology; for example, the topology onA2 D A1�A1 is not the product topology (see 2.29).

Products in general

We now define the product of two algebraic prevarieties V and W .Write V as a union of open affines V D

SVi , and note that V can be regarded as the

variety obtained by patching the .Vi ;OVi /; in particular, this covering satisfies the patchingcondition (4.13). Similarly, write W as a union of open affines W D

SWj . Then

V �W D[Vi �Wj

and the .Vi �Wj ;OVi�Wj / satisfy the patching condition. Therefore, we can define .V �W;OV�W / to be the variety obtained by patching the .Vi �Wj ;OVi�Wj /.

PROPOSITION 4.21. With the sheaf of k-algebras OV�W just defined, V �W becomes theproduct of V andW in the category of prevarieties. In particular, the structure of prevarietyon V �W defined by the coverings V D

SVi and W D

SWj are independent of the

coverings.

PROOF. Let T be a prevariety, and let 'WT ! V �W be a map of sets such that p ı' andq ı' are regular. Then (4.19) implies that the restriction of ' to '�1.Vi �Wj / is regular.As these open sets cover T , this shows that ' is regular. 2

PROPOSITION 4.22. If V and W are separated, then so also is V �W .

PROOF. Let '1;'2 be two regular maps U ! V �W . The set where '1;'2 agree is theintersection of the sets where p ı'1;p ı'2 and q ı'1;q ı'2 agree, which is closed. 2

The separation axiom revisited 81

EXAMPLE 4.23. An algebraic group is a variety G together with regular maps

multWG�G!G; inverseWG!G; A0e�!G

that make G into a group in the usual sense. For example,

SLn D Spm.kŒX11;X12; : : : ;Xnn�=.det.Xij /�1//

andGLn D Spm.kŒX11;X12; : : : ;Xnn;Y �=.Y det.Xij /�1//

become algebraic groups when endowed with their usual group structure. The only affinealgebraic groups of dimension 1 are

Gm D GL1 D SpmkŒX;X�1�

andGa D SpmkŒX�.

Any finite group N can be made into an algebraic group by setting

N D Spm.A/

with A the set of all maps f WN ! k.Affine algebraic groups are called linear algebraic groups because they can all be re-

alized as closed subgroups of GLn for some n. Connected algebraic groups that can berealized as closed algebraic subvarieties of a projective space are called abelian varietiesbecause they are related to the integrals studied by Abel (happily, they all turn out to becommutative; see 7.15 below).

The connected component Gı of an algebraic group G containing the identity compo-nent (the identity component) is a closed normal subgroup of G and the quotient G=Gı isa finite group. An important theorem of Barsotti and Chevalley says that every connectedalgebraic group G contains a unique connected linear algebraic group G1 such that G=G1is an abelian variety. Thus, we have the following coarse classification: every algebraicgroup G contains a sequence of normal subgroups

G �Gı �G1 � feg

with G=Gı a finite group, Gı=G1 an abelian variety, and G1 a linear algebraic group.

The separation axiom revisited

Now that we have the notion of the product of varieties, we can restate the separation axiomin terms of the diagonal.

By way of motivation, consider a topological space V and the diagonal �� V �V ,

�defD f.x;x/ j x 2 V g:

If � is closed (for the product topology), then every pair of points .x;y/ …� has a neigh-bourhood U �U 0 such that U �U 0\�D∅. In other words, if x and y are distinct points inV , then there are neighbourhoods U and U 0 of x and y respectively such that U \U 0 D∅.Thus V is Hausdorff. Conversely, if V is Hausdorff, the reverse argument shows that � isclosed.

For a variety V , we let �D�V (the diagonal) be the subset f.v;v/ j v 2 V g of V �V .

82 4. ALGEBRAIC VARIETIES

PROPOSITION 4.24. An algebraic prevariety V is separated if and only if �V is closed.3

PROOF. Assume �V is closed. Let '1 and '2 be regular maps Z! V . The map

.'1;'2/WZ! V �V; z 7! .'1.z/;'2.z//

is regular because its composites with the projections to V are '1 and '2. In particular, itis continuous, and so .'1;'2/�1.�/ is closed. But this is precisely the subset on which '1and '2 agree.

Conversely, suppose V is separated. This means that for any affine varietyZ and regularmaps '1;'2WZ! V , the set on which '1 and '2 agree is closed in Z. Apply this with '1and '2 the two projection maps V �V ! V , and note that the set on which they agree is�V . 2

COROLLARY 4.25. For any prevariety V , the diagonal is a locally closed subset of V �V .

PROOF. Let P 2 V , and let U be an open affine neighbourhood of P . Then U �U is anopen neighbourhood of .P;P / in V � V , and �V \ .U �U/ D �U , which is closed inU �U because U is separated (4.6). 2

Thus �V is always a subvariety of V �V , and it is closed if and only if V is separated.The graph �' of a regular map 'WV !W is defined to be

f.v;'.v// 2 V �W j v 2 V g:

At this point, the reader should draw the picture suggested by calculus.

COROLLARY 4.26. For any morphism 'WV ! W of prevarieties, the graph �' of ' islocally closed in V �W , and it is closed if W is separated. The map v 7! .v;'.v// is anisomorphism of V onto �' (as algebraic prevarieties).

PROOF. The map.v;w/ 7! .'.v/;w/WV �W !W �W

is regular because its composites with the projections are ' and idW which are regular.In particular, it is continuous, and as �' is the inverse image of �W under this map, thisproves the first statement. The second statement follows from the fact that the regular map�' ,! V �W

p! V is an inverse to v 7! .v;'.v//WV ! �' . 2

THEOREM 4.27. The following three conditions on a prevariety V are equivalent:

(a) V is separated;(b) for every pair of open affines U and U 0 in V , U \U 0 is an open affine, and the map

f ˝g 7! f jU\U 0 �gjU\U 0 WkŒU �˝k kŒU0�! kŒU \U 0�

is surjective;

3Recall that the topology on V �V is not the product topology. Thus the statement does not contradict thefact that V is not Hausdorff.

The separation axiom revisited 83

(c) the condition in (b) holds for the sets in some open affine covering of V .

PROOF. Let U and U 0 be open affines in V . We shall prove that(i) if � is closed then U \U 0 affine,(ii) when U \U 0 is affine,

.U �U 0/\� is closed ” kŒU �˝k kŒU0�! kŒU \U 0� is surjective:

Assume (a); then these statements imply (b). Assume that (b) holds for the sets in anopen affine covering .Ui /i2I of V . Then .Ui �Uj /.i;j /2I�I is an open affine covering ofV �V , and �V \ .Ui �Uj / is closed in Ui �Uj for each pair .i;j /, which implies (a).Thus, the statements (i) and (ii) imply the theorem.

Proof of (i): The graph of the inclusion U \U 0 ,! V is the subset .U �U 0/\� of.U \U 0/� V: If �V is closed, then .U �U 0/\�V is a closed subvariety of an affinevariety, and hence is affine (see p66). Now (4.26) implies that U \U 0 is affine.

Proof of (ii): Assume that U \U 0 is affine. Then

.U �U 0/\�V is closed in U �U 0

” v 7! .v;v/WU \U 0! U �U 0 is a closed immersion

” kŒU �U 0�! kŒU \U 0� is surjective (3.22).

Since kŒU �U 0�D kŒU �˝k kŒU 0�, this completes the proof of (ii). 2

In more down-to-earth terms, condition (b) says that U \U 0 is affine and every regularfunction on U \U 0 is a sum of functions of the form P 7! f .P /g.P / with f and g regularfunctions on U and U 0.

EXAMPLE 4.28. (a) Let V D P1, and let U0 and U1 be the standard open subsets (see4.3). Then U0 \U1 D A1r f0g, and the maps on rings corresponding to the inclusionsUi ,! U0\U1 are

f .X/ 7! f .X/WkŒX�! kŒX;X�1�

f .X/ 7! f .X�1/WkŒX�! kŒX;X�1�;

Thus the sets U0 and U1 satisfy the condition in (b).(b) Let V be A1 with the origin doubled (see 4.10), and let U and U 0 be the upper and

lower copies of A1 in V . Then U \U 0 is affine, but the maps on rings corresponding to theinclusions Ui ,! U0\U1 are

X 7!X WkŒX�! kŒX;X�1�

X 7!X WkŒX�! kŒX;X�1�;

Thus the sets U0 and U1 fail the condition in (b).(c) Let V beA2 with the origin doubled, and letU andU 0 be the upper and lower copies

of A2 in V . Then U \U 0 is not affine (see 3.21).

84 4. ALGEBRAIC VARIETIES

Fibred products

Consider a variety S and two regular maps 'WV ! S and WW ! S . Then the set

V �S WdefD f.v;w/ 2 V �W j '.v/D .w/g

is a closed subvariety of V �W (because it is the set where ' ıp and ı q agree). It iscalled the fibred product of V and W over S . Note that if S consists of a single point, thenV �S W D V �W .

Write '0 for the map .v;w/ 7!wWV �S W !W and 0 for the map .v;w/ 7! vWV �SW ! V . We then have a commutative diagram:

V �S W'0

����! W??y 0 ??y V

'����! S:

The fibred product has the following universal property: consider a pair of regular maps˛WT ! V , ˇWT !W ; then

t 7! .˛.t/, ˇ.t//WT ! V �W

factors through V �S W (as a map of sets) if and only if '˛ D ˇ, in which case .˛;ˇ/ isregular (because it is regular as a map into V �W /;

T

V �S W W

V S

ˇ

˛

.˛;ˇ/

�

The map '0 in the above diagram is called the base change of ' with respect to .For any point P 2 S , the base change of 'WV ! S with respect to P ,! S is the map'�1.P /! P induced by ', which is called the fibre of V over P .

EXAMPLE 4.29. If f WV ! S is a regular map and U is an open subvariety of S , thenV �S U is the inverse image of U in S .

EXAMPLE 4.30. Since a tensor product of rings A˝RB has the opposite universal prop-erty to that of a fibred product, one might hope that

Spm.A/�Spm.R/ Spm.B/ ‹‹D Spm.A˝RB/:

This is true if A˝RB is an affine k-algebra, but in general it may have nilpotent4 elements.For example, let RD kŒX�, let AD k with the R-algebra structure sending X to a, and let

4By this, of course, we mean nonzero nilpotent elements.

Dimension 85

B D kŒX� with the R-algebra structure sendingX toXp. When k has characteristic p¤ 0,then

A˝RB ' k˝kŒXp� kŒX�' kŒX�=.Xp�a/:

The correct statement is

Spm.A/�Spm.R/ Spm.B/' Spm.A˝RB=N/ (9)

where N is the ideal of nilpotent elements in A˝R B . To prove this, note that for anyvariety T ,

Mor.T;Spm.A˝RB=N//' Hom.A˝RB=N;� .T;OT //' Hom.A˝RB;� .T;OT //' Hom.A;� .T;OT //�Hom.R;� .T;OT //Hom.B;� .T;OT //'Mor.V;Spm.A//�Mor.V;Spm.R//Mor.V;Spm.B//:

For the first and fourth isomorphisms, we used (4.11); for the second isomorphism, we usedthat � .T;OT / has no nilpotents; for the third isomorphism, we used the universal propertyof A˝RB .

Dimension

In an irreducible algebraic variety V , every nonempty open subset is dense and irreducible.If U and U 0 are open affines in V , then so also is U \U 0 and

kŒU �� kŒU \U 0�� k.U /

where k.U / is the field of fractions of kŒU �, and so k.U / is also the field of fractions ofkŒU \U 0� and of kŒU 0�. Thus, we can attach to V a field k.V /, called the field of rationalfunctions on V , such that for every open affine U in V , k.V / is the field of fractions ofkŒU �. The dimension of V is defined to be the transcendence degree of k.V / over k. Notethe dim.V /D dim.U / for any open subset U of V . In particular, dim.V /D dim.U / for Uan open affine in V . It follows that some of the results in �2 carry over — for example, ifZ is a proper closed subvariety of V , then dim.Z/ < dim.V /.

PROPOSITION 4.31. Let V and W be irreducible varieties. Then

dim.V �W /D dim.V /Cdim.W /:

PROOF. We may suppose V and W to be affine. Write

kŒV �D kŒx1; : : : ;xm�

kŒW �D kŒy1; : : : ;yn�

where the x’s and y’s have been chosen so that fx1; : : : ;xd g and fy1; : : : ;yeg are maxi-mal algebraically independent sets of elements of kŒV � and kŒW �. Then fx1; : : : ;xd g andfy1; : : : ;yeg are transcendence bases of k.V / and k.W / (see FT 8.12), and so dim.V /D dand dim.W /D e. Then5

kŒV �W �defD kŒV �˝k kŒW �� kŒx1; : : : ;xd �˝k kŒy1; : : : ;ye�' kŒx1; : : : ;xd ;y1; : : : ;ye�:

5In general, it is not true that if M 0 and N 0 are R-submodules of M and N , then M 0˝R N 0 is an R-submodule of M ˝RN . However, this is true if R is a field, because then M 0 and N 0 will be direct summandsof M and N , and tensor products preserve direct summands.

86 4. ALGEBRAIC VARIETIES

Therefore fx1˝1; : : : ;xd˝1;1˝y1; : : : ;1˝yegwill be algebraically independent in kŒV �˝kkŒW �. Obviously kŒV �W � is generated as a k-algebra by the elements xi ˝ 1, 1˝ yj ,1� i �m, 1� j � n, and all of them are algebraic over

kŒx1; : : : ;xd �˝k kŒy1; : : : ;ye�:

Thus the transcendence degree of k.V �W / is d C e. 2

We extend the definition of dimension to an arbitrary variety V as follows. An algebraicvariety is a finite union of noetherian topological spaces, and so is noetherian. Consequently(see 2.21), V is a finite union V D

SVi of its irreducible components, and we define

dim.V /Dmaxdim.Vi /. When all the irreducible components of V have dimension n; V issaid to be pure of dimension n (or to be of pure dimension n).

Birational equivalence

Two irreducible varieties V and W are said to be birationally equivalent if k.V /� k.W /.

PROPOSITION 4.32. Two irreducible varieties V and W are birationally equivalent if andonly if there are open subsets U and U 0 of V and W respectively such that U � U 0.

PROOF. Assume that V andW are birationally equivalent. We may suppose that V andWare affine, corresponding to the rings A and B say, and that A and B have a common fieldof fractions K. Write B D kŒx1; : : : ;xn�. Then xi D ai=bi , ai ;bi 2 A, and B � Ab1:::br .Since Spm.Ab1:::br / is a basic open subvariety of V , we may replace A with Ab1:::br , andsuppose that B � A. The same argument shows that there exists a d 2 B � A such thatA� Bd . Now

B � A� Bd ) Bd � Ad � .Bd /d D Bd ;

and so Ad D Bd . This shows that the open subvarieties D.b/ � V and D.b/ � W areisomorphic. This proves the “only if” part, and the “if” part is obvious. 2

REMARK 4.33. Proposition 4.32 can be improved as follows: if V and W are irreduciblevarieties, then every inclusion k.V /� k.W / is defined by a regular surjective map 'WU !U 0 from an open subset U of W onto an open subset U 0 of V .

PROPOSITION 4.34. Every irreducible algebraic variety of dimension d is birationallyequivalent to a hypersurface in AdC1.

PROOF. Let V be an irreducible variety of dimension d . According to FT 8.21, there existalgebraically independent elements x1; : : : ;xd 2 k.V / such that k.V / is finite and separableover k.x1; : : : ;xd /. By the primitive element theorem (FT 5.1), k.V /D k.x1; : : : ;xd ;xdC1/for some xdC1. Let f 2 kŒX1; : : : ;XdC1� be an irreducible polynomial satisfied by the xi ,and let H be the hypersurface f D 0. Then k.V /� k.H/. 2

REMARK 4.35. An irreducible variety V of dimension d is said to rational if it is bira-tionally equivalent to Ad . It is said to be unirational if k.V / can be embedded in k.Ad /—according to (4.33), this means that there is a regular surjective map from an open subset of

Dominant maps 87

AdimV onto an open subset of V . Luroth’s theorem (cf. FT 8.19) says that every unirationalcurve is rational. It was proved by Castelnuovo that when k has characteristic zero everyunirational surface is rational. Only in the seventies was it shown that this is not true forthree dimensional varieties (Artin, Mumford, Clemens, Griffiths, Manin,...). When k hascharacteristic p ¤ 0, Zariski showed that there exist nonrational unirational surfaces, andP. Blass showed that there exist infinitely many surfaces V , no two birationally equivalent,such that k.Xp;Y p/� k.V /� k.X;Y /.

Dominant maps

As in the affine case, a regular map 'WV ! W is said to be dominant (or dominating)if the image of ' is dense in W . Suppose V and W are irreducible. If V 0 and W 0 areopen affine subsets of V and W such that '.V 0/ � W 0, then (3.22) implies that the mapf 7! f ı 'WkŒW 0�! kŒV 0� is injective. Therefore it extends to a map on the fields offractions, k.W /! k.V /, and this map is independent of the choice of V 0 and W 0.

Algebraic varieties as a functors

Let A be an affine k-algebra, and let V be an algebraic variety. We define a point of V withcoordinates in A to be a regular map Spm.A/! V . For example, if V D V.a/� kn, then

V.A/D f.a1; : : : ;an/ 2 Anj f .a1; : : : ;an/D 0 all f 2 ag;

which is what you should expect. In particular V.k/D V (as a set), i.e., V (as a set) can beidentified with the set of points of V with coordinates in k. Note that

.V �W /.A/D V.A/�W.A/

(property of a product).

REMARK 4.36. Let V be the union of two subvarieties, V D V1[V2. If V1 and V2 areboth open, then V.A/ D V1.A/[V2.A/, but not necessarily otherwise. For example, forany polynomial f .X1; : : : ;Xn/,

An DDf [V.f /

where Df ' Spm.kŒX1; : : : ;Xn;T �=.1�Tf // and V.f / is the zero set of f , but

An ¤ fa 2 An j f .a/ 2 A�g[fa 2 An j f .a/D 0g

in general.

THEOREM 4.37. A regular map 'WV !W of algebraic varieties defines a family of mapsof sets, '.A/WV.A/! W.A/, one for each affine k-algebra A, such that for every homo-morphism ˛WA! B of affine k-algebras,

A V.A/'.A/����! W.A/??y˛ ??yV.˛/ ??yV.ˇ/

B V.B/'.B/����! W.B/

(*)

88 4. ALGEBRAIC VARIETIES

commutes. Every family of maps with this property arises from a unique morphism ofalgebraic varieties.

For a variety V , let haffV be the functor sending an affine k-algebra A to V.A/. We can

restate as Theorem 4.37 follows.

THEOREM 4.38. The functor

V 7! haffV WVark! Fun.Affk;Sets/

if fully faithful.

PROOF. The Yoneda lemma (1.38) shows that the functor

V 7! hV WVark! Fun.Vark;Sets/

is fully faithful. Let ' be a morphism haffV ! haff

V 0 , and let T be a variety. Let .Ui /i2I be afinite affine covering of T . Each intersection Ui \Uj is affine (4.27), and so ' gives rise toa commutative diagram

0 ! hV .T / !Qi hV .Ui / ⇒

Qi;j hV .Ui \Uj /

# #

0 ! hV 0.T / !Qi hV 0.Ui / ⇒

Qi;j hV 0.Ui \Uj /

in which the pairs of maps are defined by the inclusions Ui \Uj ,! Ui ;Uj . As the rowsare exact (4.13), this shows that 'V extends uniquely to a functor hV ! hV 0 , which (by theYoneda lemma) arises from a unique regular map V ! V 0. 2

COROLLARY 4.39. To give an affine algebraic group is the same as to give a functorGWAffk!Gp such that for some n and some finite set S of polynomials in kŒX1;X2; : : : ;Xn�,G.A/ is the set of zeros of S in An.

PROOF. Certainly an affine algebraic group defines such a functor. Conversely, the con-ditions imply that G D hV for an affine algebraic variety V (unique up to a unique iso-morphism). The multiplication maps G.A/�G.A/! G.A/ give a morphism of functorshV �hV ! hV . As hV �hV ' hV�V (by definition of V �V ), we see that they arise froma regular map V �V ! V . Similarly, the inverse map and the identity-element map areregular. 2

It is not unusual for a variety to be most naturally defined in terms of its points functor.

REMARK 4.40. The essential image of h 7! hV WVaraffk! Fun.Affk;Sets/ consists of the

functors F defined by some (finite) set of polynomials.

We now describe the essential image of h 7! hV WVark ! Fun.Affk;Sets/. The fibreproduct of two maps ˛1WF1! F3, ˛2WF2! F3 of sets is the set

F1�F3 F2 D f.x1;x2/ j ˛1.x1/D ˛2.x2/g:

Exercises 89

When F1;F2;F3 are functors and ˛1;˛2;˛3 are morphisms of functors, there is a functorF D F1�F3 F2 such that

.F1�F3 F2/.A/D F1.A/�F3.A/F2.A/

for all affine k-algebras A.To simplify the statement of the next proposition, we write U for hU when U is an

affine variety.

PROPOSITION 4.41. A functor F WAffk! Sets is in the essential image of Vark if and onlyif there exists an affine scheme U and a morphism U ! F such that

(a) the functor R defDU �F U is a closed affine subvariety of U �U and the maps R⇒U

defined by the projections are open immersions;(b) the set R.k/ is an equivalence relation on U.k/, and the map U.k/! F.k/ realizes

F.k/ as the quotient of U.k/ by R.k/.

PROOF. Let F D hV for V an algebraic variety. Choose a finite open affine coveringV D

SUi of V , and let U D

FUi . It is again an affine variety (Exercise 4-2). The functor

R is hU 0 where U 0 is the disjoint union of the varieties Ui \Uj . These are affine (4.27),and so U 0 is affine. As U 0 is the inverse image of �V in U �U , it is closed (4.24). Thisproves (a), and (b) is obvious.

The converse is omitted for the present. 2

REMARK 4.42. A variety V defines a functor R 7! V.R/ from the category of all k-algebras to Sets. For example, if V is affine,

V.R/D Homk-algebra.kŒV �;R/:

More explicitly, if V � kn and I.V / D .f1; : : : ;fm/, then V.R/ is the set of solutions inRn of the system equations

fi .X1; : : : ;Xn/D 0; i D 1; : : : ;m:

Again, we call the elements of V.R/ the points of V with coordinates in R.Note that, when we allow R to have nilpotent elements, it is important to choose the fi

to generate I.V / (i.e., a radical ideal) and not just an ideal a such that V.a/D V .6

Exercises

4-1. Show that the only regular functions on P1 are the constant functions. [Thus P1 isnot affine. When k DC, P1 is the Riemann sphere (as a set), and one knows from complexanalysis that the only holomorphic functions on the Riemann sphere are constant. Sinceregular functions are holomorphic, this proves the statement in this case. The general caseis easier.]

6Let a be an ideal in kŒX1; : : :�. If A has no nonzero nilpotent elements, then every k-algebra homomor-phism kŒX1; : : :�! A that is zero on a is also zero on rad.a/, and so

Homk.kŒX1; : : :�=a;A/' Homk.kŒX1; : : :�=rad.a/;A/:

This is not true if A has nonzero nilpotents.

90 4. ALGEBRAIC VARIETIES

4-2. Let V be the disjoint union of algebraic varieties V1; : : : ;Vn. This set has an obvioustopology and ringed space structure for which it is an algebraic variety. Show that V isaffine if and only if each Vi is affine.

4-3. Show that every algebraic subgroup of an algebraic group is closed.

CHAPTER 5Local Study

In this chapter, we examine the structure of a variety near a point. We begin with thecase of a curve, since the ideas in the general case are the same but the formulas are morecomplicated. Throughout, k is an algebraically closed field.

Tangent spaces to plane curves

Consider the curveV W F.X;Y /D 0

in the plane defined by a nonconstant polynomial F.X;Y /. We assume that F.X;Y / hasno multiple factors, so that .F.X;Y // is a radical ideal and I.V / D .F.X;Y //. We canfactor F into a product of irreducible polynomials, F.X;Y /D

QFi .X;Y /, and then V DS

V.Fi / expresses V as a union of its irreducible components. Each component V.Fi /has dimension 1 (see 2.25) and so V has pure dimension 1. More explicitly, suppose forsimplicity that F.X;Y / itself is irreducible, so that

kŒV �D kŒX;Y �=.F.X;Y //D kŒx;y�

is an integral domain. If F ¤X �c, then x is transcendental over k and y is algebraic overk.x/, and so x is a transcendence basis for k.V / over k. Similarly, if F ¤ Y � c, then y isa transcendence basis for k.V / over k.

Let .a;b/ be a point on V . In calculus, the equation of the tangent at P D .a;b/ isdefined to be

@F

@X.a;b/.X �a/C

@F

@Y.a;b/.Y �b/D 0: (10)

This is the equation of a line unless both @F@X.a;b/ and @F

@Y.a;b/ are zero, in which case it is

the equation of a plane.

DEFINITION 5.1. The tangent space TPV to V at P D .a;b/ is the space defined byequation (10).

When @F@X.a;b/ and @F

@Y.a;b/ are not both zero, TP .V / is a line, and we say that P is

a nonsingular or smooth point of V . Otherwise, TP .V / has dimension 2, and we say thatP is singular or multiple. The curve V is said to be nonsingular or smooth when all itspoints are nonsingular.

91

92 5. LOCAL STUDY

We regard TP .V / as a subspace of the two-dimensional vector space TP .A2/, which isthe two-dimensional space of vectors with origin P .

EXAMPLE 5.2. For each of the following examples, the reader (or his computer) is invitedto sketch the curve.1 The characteristic of k is assumed to be¤ 2;3.

(a) XmC Y m D 1. All points are nonsingular unless the characteristic divides m (inwhich case XmCY m�1 has multiple factors).

(b) Y 2 DX3. Here only .0;0/ is singular.(c) Y 2 DX2.XC1/. Here again only .0;0/ is singular.(d) Y 2 DX3CaXCb. In this case,

V is singular ” Y 2�X3�aX �b, 2Y , and 3X2Ca have a common zero

” X3CaXCb and 3X2Ca have a common zero.

Since 3X2Ca is the derivative ofX3CaXCb, we see that V is singular if and onlyif X3CaXCb has a multiple root.

(e) .X2CY 2/2C3X2Y �Y 3 D 0. The origin is (very) singular.(f) .X2CY 2/3�4X2Y 2 D 0. The origin is (even more) singular.(g) V D V.FG/ where FG has no multiple factors and F and G are relatively prime.

Then V D V.F /[V.G/, and a point .a;b/ is singular if and only if it is a singularpoint of V.F /, a singular point of V.G/, or a point of V.F /\V.G/. This followsimmediately from the equations given by the product rule:

@.FG/

@XD F �

@G

@XC@F

@X�G;

@.FG/

@YD F �

@G

@YC@F

@Y�G:

PROPOSITION 5.3. Let V be the curve defined by a nonconstant polynomial F withoutmultiple factors. The set of nonsingular points2 is an open dense subset V .

PROOF. We can assume that F is irreducible. We have to show that the set of singularpoints is a proper closed subset. Since it is defined by the equations

F D 0;@F

@XD 0;

@F

@YD 0;

it is obviously closed. It will be proper unless @F=@X and @F=@Y are identically zero on V ,and are therefore both multiples of F , but, since they have lower degree, this is impossibleunless they are both zero. Clearly @F=@X D 0 if and only if F is a polynomial in Y (kof characteristic zero) or is a polynomial in Xp and Y (k of characteristic p/. A similarremark applies to @F=@Y . Thus if @F=@X and @F=@Y are both zero, then F is constant(characteristic zero) or a polynomial in Xp, Y p, and hence a pth power (characteristic p/.These are contrary to our assumptions. 2

The set of singular points of a variety is called the singular locus of the variety.

1For (b,e,f), see p57 of: Walker, Robert J., Algebraic Curves. Princeton Mathematical Series, vol. 13.Princeton University Press, Princeton, N. J., 1950 (reprinted by Dover 1962).

2In common usage, “singular” means uncommon or extraordinary as in “he spoke with singular shrewd-ness”. Thus the proposition says that singular points (mathematical sense) are singular (usual sense).

Tangent cones to plane curves 93

Tangent cones to plane curves

A polynomial F.X;Y / can be written (uniquely) as a finite sum

F D F0CF1CF2C�� �CFmC�� � (11)

where Fm is a homogeneous polynomial of degree m. The term F1 will be denoted F` andcalled the linear form of F , and the first nonzero term on the right of (11) (the homogeneoussummand of F of least degree) will be denoted F� and called the leading form of F .

If P D .0;0/ is on the curve V defined by F , then F0 D 0 and (11) becomes

F D aXCbY Chigher degree terms;

moreover, the equation of the tangent space is

aXCbY D 0:

DEFINITION 5.4. Let F.X;Y / be a polynomial without square factors, and let V be thecurve defined by F . If .0;0/ 2 V , then the geometric tangent cone to V at .0;0/ is the zeroset of F�. The tangent cone is the pair .V .F�/;F�/. To obtain the tangent cone at any otherpoint, translate to the origin, and then translate back.

EXAMPLE 5.5. (a) Y 2DX3: the tangent cone at .0;0/ is defined by Y 2 — it is theX -axis(doubled).

(b) Y 2 D X2.XC1/: the tangent cone at (0,0) is defined by Y 2�X2 — it is the pairof lines Y D˙X .

(c) .X2CY 2/2C3X2Y �Y 3 D 0: the tangent cone at .0;0/ is defined by 3X2Y �Y 3

— it is the union of the lines Y D 0, Y D˙p3X .

(d) .X2CY 2/3�4X2Y 2 D 0W the tangent cone at .0;0/ is defined by 4X2Y 2 D 0 —it is the union of the X and Y axes (each doubled).

In general we can factor F� as

F�.X;Y /DYXr0.Y �aiX/

ri :

Then degF� DPri is called the multiplicity of the singularity, multP .V /. A multiple

point is ordinary if its tangents are nonmultiple, i.e., ri D 1 all i . An ordinary double pointis called a node, and a nonordinary double point is called a cusp. (There are many namesfor special types of singularities — see any book, especially an old book, on curves.)

The local ring at a point on a curve

PROPOSITION 5.6. Let P be a point on a curve V , and let m be the corresponding maximalideal in kŒV �. If P is nonsingular, then dimk.m=m2/D 1, and otherwise dimk.m=m2/D 2.

94 5. LOCAL STUDY

PROOF. Assume first that P D .0;0/. Then m D .x;y/ in kŒV � D kŒX;Y �=.F.X;Y // DkŒx;y�. Note that m2 D .x2;xy;y2/, and

m=m2 D .X;Y /=.m2CF.X;Y //D .X;Y /=.X2;XY;Y 2;F .X;Y //:

In this quotient, every element is represented by a linear polynomial cxC dy, and theonly relation is F`.x;y/D 0. Clearly dimk.m=m2/D 1 if F` ¤ 0, and dimk.m=m2/D 2otherwise. Since F` D 0 is the equation of the tangent space, this proves the proposition inthis case.

The same argument works for an arbitrary point .a;b/ except that one uses the variablesX 0 DX �a and Y 0 D Y �b; in essence, one translates the point to the origin. 2

We explain what the condition dimk.m=m2/D 1means for the local ring OP D kŒV �m.Let n be the maximal ideal mkŒV �m of this local ring. The map m! n induces an isomor-phism m=m2! n=n2 (see 1.31), and so we have

P nonsingular ” dimkm=m2D 1 ” dimk n=n

2D 1:

Nakayama’s lemma (1.3) shows that the last condition is equivalent to n being a principalideal. Since OP is of dimension 1, n being principal means OP is a regular local ring ofdimension 1 (1.6), and hence a discrete valuation ring, i.e., a principal ideal domain withexactly one prime element (up to associates) (CA 17.4). Thus, for a curve,

P nonsingular ” OP regular ” OP is a discrete valuation ring.

Tangent spaces of subvarieties of Am

Before defining tangent spaces at points of closed subvarietes of Am we review some ter-minology from linear algebra.

Linear algebra

For a vector space km, let Xi be the i th coordinate function a 7! ai . Thus X1; : : : ;Xm isthe dual basis to the standard basis for km. A linear form

PaiXi can be regarded as an

element of the dual vector space .km/_ D Hom.km;k/.Let AD .aij / be an n�m matrix. It defines a linear map ˛Wkm! kn, by0B@ a1

:::

am

1CA 7! A

0B@ a1:::

am

1CAD0B@PmjD1a1jaj

:::PmjD1anjaj

1CA :Write X1; : : : ;Xm for the coordinate functions on km and Y1; : : : ;Yn for the coordinatefunctions on kn. Then

Yi ı˛ D

mXjD1

aijXj :

This says that, when we apply ˛ to a, then the i th coordinate of the result is

mXjD1

aij .Xj a/DmXjD1

aijaj :

Tangent spaces of subvarieties of Am 95

Tangent spaces

Consider an affine variety V � km, and let a D I.V /. The tangent space Ta.V / to Vat a D .a1; : : : ;am/ is the subspace of the vector space with origin a cut out by the linearequations

mXiD1

@F

@Xi

ˇa.Xi �ai /D 0; F 2 a. (12)

Thus Ta.Am/ is the vector space of dimension m with origin a, and Ta.V / is the subspaceof Ta.Am/ defined by the equations (12).

Write .dXi /a for .Xi � ai /; then the .dXi /a form a basis for the dual vector spaceTa.Am/_ to Ta.Am/ — in fact, they are the coordinate functions on Ta.Am/_. As in ad-vanced calculus, we define the differential of a polynomial F 2 kŒX1; : : : ;Xm� at a by theequation:

.dF /a D

nXiD1

@F

@Xi

ˇa.dXi /a:

It is again a linear form on Ta.Am/. In terms of differentials, Ta.V / is the subspace ofTa.Am/ defined by the equations:

.dF /a D 0; F 2 a; (13)

I claim that, in (12) and (13), it suffices to take the F in a generating subset for a. Theproduct rule for differentiation shows that if G D

Pj HjFj , then

.dG/a DXj

Hj .a/ � .dFj /aCFj .a/ � .dHj /a:

If F1; : : : ;Fr generate a and a 2 V.a/, so that Fj .a/ D 0 for all j , then this equation be-comes

.dG/a DXj

Hj .a/ � .dFj /a:

Thus .dF1/a; : : : ; .dFr/a generate the k-space f.dF /a j F 2 ag.When V is irreducible, a point a on V is said to be nonsingular (or smooth) if the

dimension of the tangent space at a is equal to the dimension of V ; otherwise it is singular(or multiple). When V is reducible, we say a is nonsingular if dimTa.V / is equal to themaximum dimension of an irreducible component of V passing through a. It turns out thenthat a is singular precisely when it lies on more than one irreducible component, or when itlies on only one component but is a singular point of that component.

Let aD .F1; : : : ;Fr/, and let

J D Jac.F1; : : : ;Fr/D�@Fi

@Xj

�D

0BB@@F1@X1

; : : : ; @F1@Xm

::::::

@Fr@X1

; : : : ; @Fr@Xm

1CCA :Then the equations defining Ta.V / as a subspace of Ta.Am/ have matrix J.a/. Therefore,linear algebra shows that

dimk Ta.V /Dm� rankJ.a/;

96 5. LOCAL STUDY

and so a is nonsingular if and only if the rank of Jac.F1; : : : ;Fr/.a/ is equal tom�dim.V /.For example, if V is a hypersurface, say I.V /D .F.X1; : : : ;Xm//, then

Jac.F /.a/D�@F

@X1.a/; : : : ;

@F

@Xm.a/�;

and a is nonsingular if and only if not all of the partial derivatives @F@Xi

vanish at a.We can regard J as a matrix of regular functions on V . For each r ,

fa 2 V j rankJ.a/� rg

is closed in V , because it is the set where certain determinants vanish. Therefore, thereis an open subset U of V on which rankJ.a/ attains its maximum value, and the rankjumps on closed subsets. Later (5.18) we shall show that the maximum value of rankJ.a/is m�dimV , and so the nonsingular points of V form a nonempty open subset of V .

The differential of a regular map

Consider a regular map

'WAm! An; a 7! .P1.a1; : : : ;am/; : : : ;Pn.a1; : : : ;am//:

We think of ' as being given by the equations

Yi D Pi .X1; : : : ;Xm/, i D 1; : : :n:

It corresponds to the map of rings '�WkŒY1; : : : ;Yn�! kŒX1; : : : ;Xm� sending Yi toPi .X1; : : : ;Xm/,i D 1; : : :n.

Let a 2Am, and let bD '.a/. Define .d'/aWTa.Am/! Tb.An/ to be the map such that

.dYi /b ı .d'/a DX @Pi

@Xj

ˇa.dXj /a;

i.e., relative to the standard bases, .d'/a is the map with matrix

Jac.P1; : : : ;Pn/.a/D

0BB@@P1@X1

.a/; : : : ; @P1@Xm

.a/:::

:::@Pn@X1

.a/; : : : ; @Pn@Xm

.a/

1CCA :For example, suppose aD .0; : : : ;0/ and bD .0; : : : ;0/, so that Ta.Am/D km and Tb.An/Dkn, and

Pi D

mXjD1

cijXj C .higher terms), i D 1; : : : ;n:

Then Yi ı .d'/a DPj cijXj , and the map on tangent spaces is given by the matrix .cij /,

i.e., it is simply t 7! .cij /t.Let F 2 kŒX1; : : : ;Xm�. We can regard F as a regular mapAm!A1, whose differential

will be a linear map

.dF /aWTa.Am/! Tb.A1/; bD F.a/:

When we identify Tb.A1/ with k, we obtain an identification of the differential of F (Fregarded as a regular map) with the differential of F (F regarded as a regular function).

Etale maps 97

LEMMA 5.7. Let 'WAm! An be as at the start of this subsection. If ' maps V D V.a/�km into W D V.b/� kn, then .d'/a maps Ta.V / into Tb.W /, bD '.a/.

PROOF. We are given thatf 2 b) f ı' 2 a;

and have to prove that

f 2 b) .df /b ı .d'/a is zero on Ta.V /:

The chain rule holds in our situation:

@f

@XiD

nXjD1

@f

@Yj

@Yj

@Xi; Yj D Pj .X1; : : : ;Xm/; f D f .Y1; : : : ;Yn/:

If ' is the map given by the equations

Yj D Pj .X1; : : : ;Xm/; j D 1; : : : ;n;

then the chain rule implies

d.f ı'/a D .df /b ı .d'/a; bD '.a/:

Let t 2 Ta.V /; then.df /b ı .d'/a.t/D d.f ı'/a.t/;

which is zero if f 2 b because then f ı' 2 a. Thus .d'/a.t/ 2 Tb.W /. 2

We therefore get a map .d'/aWTa.V /! Tb.W /. The usual rules from advanced calcu-lus hold. For example,

.d /b ı .d'/a D d. ı'/a; bD '.a/:

The definition we have given of Ta.V / appears to depend on the embedding V ,!

An. Later we shall give an intrinsic of the tangent space, which is independent of anyembedding.

EXAMPLE 5.8. Let V be the union of the coordinate axes in A3, and let W be the zero setof XY.X �Y / in A2. Each of V and W is a union of three lines meeting at the origin. Arethey isomorphic as algebraic varieties? Obviously, the origin o is the only singular point onV or W . An isomorphism V ! W would have to send the singular point to the singularpoint, i.e., o 7! o, and map To.V / isomorphically onto To.W /. But V D V.XY;YZ;XZ/,and so To.V / has dimension 3, whereas ToW has dimension 2. Therefore, they are notisomorphic.

Etale maps

DEFINITION 5.9. A regular map 'WV !W of smooth varieties is etale at a point P of Vif .d'/P WTP .V /! T'.P /.W / is an isomorphism; ' is etale if it is etale at all points of V .

98 5. LOCAL STUDY

EXAMPLE 5.10. (a) A regular map

'WAn! An, a 7! .P1.a1; : : : ;an/; : : : ;Pn.a1; : : : ;an//

is etale at a if and only if rankJac.P1; : : : ;Pn/.a/ D n, because the map on the tangentspaces has matrix Jac.P1; : : : ;Pn/.a/). Equivalent condition: det

�@Pi@Xj

.a/�¤ 0

(b) Let V D Spm.A/ be an affine variety, and let f DPciX

i 2 AŒX� be such thatAŒX�=.f .X// is reduced. Let W D Spm.AŒX�=.f .X//, and consider the map W ! V

corresponding to the inclusion A ,! AŒX�=.f /. Thus

AŒX�=.f / AŒX� W V �A1

A V

The points of W lying over a point a 2 V are the pairs .a;b/ 2 V �A1 such that b is a rootofPci .a/X i . I claim that the mapW ! V is etale at .a;b/ if and only if b is a simple root

ofPci .a/X i .

To see this, write AD SpmkŒX1; : : : ;Xn�=a, aD .f1; : : : ;fr/, so that

AŒX�=.f /D kŒX1; : : : ;Xn�=.f1; : : : ;fr ;f /:

The tangent spaces toW and V at .a;b/ and a respectively are the null spaces of the matrices0BBBB@@f1@X1

.a/ : : : @f1@Xm

.a/ 0:::

:::@fn@X1

.a/ : : : @fn@Xm

.a/ 0@f@X1

.a/ : : : @f@Xm

.a/ @f@X.a;b/

1CCCCA0BB@

@f1@X1

.a/ : : : @f1@Xm

.a/:::

:::@fn@X1

.a/ : : : @fn@Xm

.a/

1CCAand the map T.a;b/.W /! Ta.V / is induced by the projection map knC1! kn omitting thelast coordinate. This map is an isomorphism if and only if @f

@X.a;b/¤ 0, because then any

solution of the smaller set of equations extends uniquely to a solution of the larger set. But

@f

@X.a;b/D

d.Pi ci .a/X i /dX

.b/;

which is zero if and only if b is a multiple root ofPi ci .a/X i . The intuitive picture is

that W ! V is a finite covering with deg.f / sheets, which is ramified exactly at the pointswhere two or more sheets cross.

(c) Consider a dominant map 'WW ! V of smooth affine varieties, corresponding toa map A! B of rings. Suppose B can be written B D AŒY1; : : : ;Yn�=.P1; : : : ;Pn/ (samenumber of polynomials as variables). A similar argument to the above shows that ' is etaleif and only if det

�@Pi@Xj

.a/�

is never zero.(d) The example in (b) is typical; in fact every etale map is locally of this form, provided

V is normal (in the sense defined below p105). More precisely, let 'WW ! V be etale

Intrinsic definition of the tangent space 99

at P 2 W , and assume V to normal; then there exist a map '0WW 0 ! V 0 with kŒW 0� DkŒV 0�ŒX�=.f .X//, and a commutative diagram

W � U1 � U 01 � W 0??y' ??y ??y ??y'0V � U2 � U 02 � V 0

with the U ’s all open subvarieties and P 2 U1.

� In advanced calculus (or differential topology, or complex analysis), the inversefunction theorem says that a map ' that is etale at a point a is a local isomorphism

there, i.e., there exist open neighbourhoods U and U 0 of a and '.a/ such that ' induces anisomorphism U ! U 0. This is not true in algebraic geometry, at least not for the Zariskitopology: a map can be etale at a point without being a local isomorphism. Consider forexample the map

'WA1r f0g ! A1r f0g; a 7! a2:

This is etale if the characteristic is¤ 2, because the Jacobian matrix is .2X/, which has rankone for all X ¤ 0 (alternatively, it is of the form (5.10b) with f .X/DX2�T , where T isthe coordinate function onA1, andX2�c has distinct roots for c¤ 0). Nevertheless, I claimthat there do not exist nonempty open subsets U and U 0 of A1�f0g such that ' defines anisomorphism U ! U 0. If there did, then ' would define an isomorphism kŒU 0�! kŒU �

and hence an isomorphism on the fields of fractions k.A1/! k.A1/. But on the fields offractions, ' defines the map k.X/! k.X/, X 7!X2, which is not an isomorphism.

ASIDE 5.11. There is an old conjecture that any etale map 'WAn!An is an isomorphism.If we write ' D .P1; : : : ;Pn/, then this becomes the statement:

if det�@Pi

@Xj.a/�

is never zero (for a 2 kn), then ' has a inverse.

The condition, det�@Pi@Xj

.a/�

never zero, implies that det�@Pi@Xj

�is a nonzero constant (by

the Nullstellensatz 2.6 applied to the ideal generated by det�@Pi@Xj

�). This conjecture, which

is known as the Jacobian conjecture, has not been settled even for k DC and nD 2, despitethe existence of several published proofs and innumerable announced proofs. It has causedmany mathematicians a good deal of grief. It is probably harder than it is interesting. SeeBass et al. 19823.

Intrinsic definition of the tangent space

The definition we have given of the tangent space at a point used an embedding of thevariety in affine space. In this section, we give an intrinsic definition that depends only ona small neighbourhood of the point.

3Bass, Hyman; Connell, Edwin H.; Wright, David. The Jacobian conjecture: reduction of degree andformal expansion of the inverse. Bull. Amer. Math. Soc. (N.S.) 7 (1982), no. 2, 287–330.

100 5. LOCAL STUDY

LEMMA 5.12. Let c be an ideal in kŒX1; : : : ;Xn� generated by linear forms `1; : : : ; `r ,which we may assume to be linearly independent. Let Xi1 ; : : : ;Xin�r be such that

f`1; : : : ; `r ;Xi1 ; : : : ;Xin�r g

is a basis for the linear forms in X1; : : : ;Xn. Then

kŒX1; : : : ;Xn�=c' kŒXi1 ; : : : ;Xin�r �:

PROOF. This is obvious if the forms areX1; : : : ;Xr . In the general case, because fX1; : : : ;Xngand f`1; : : : ; `r ;Xi1 ; : : : ;Xin�r g are both bases for the linear forms, each element of one setcan be expressed as a linear combination of the elements of the other. Therefore,

kŒX1; : : : ;Xn�D kŒ`1; : : : ; `r ;Xi1 ; : : : ;Xin�r �;

and so

kŒX1; : : : ;Xn�=cD kŒ`1; : : : ; `r ;Xi1 ; : : : ;Xin�r �=c

' kŒXi1 ; : : : ;Xin�r �: 2

Let V D V.a/ � kn, and assume that the origin o lies on V . Let a` be the ideal gen-erated by the linear terms f` of the f 2 a. By definition, To.V / D V.a`/. Let A` DkŒX1; : : : ;Xn�=a`, and let m be the maximal ideal in kŒV � consisting of the functions zeroat o; thus mD .x1; : : : ;xn/.

PROPOSITION 5.13. There are canonical isomorphisms

Homk-linear.m=m2;k/

'�! Homk-alg.A`;k/

'�! To.V /:

PROOF. First isomorphism: Let n D .X1; : : : ;Xn/ be the maximal ideal at the origin inkŒX1; : : : ;Xn�. Then m=m2 ' n=.n2C a/, and as f �f` 2 n2 for every f 2 a, it followsthat m=m2 ' n=.n2Ca`/. Let f1;`; : : : ;fr;` be a basis for the vector space a`. From linearalgebra we know that there are n� r linear forms Xi1 ; : : : ;Xin�r forming with the fi;` abasis for the linear forms on kn. Then Xi1 Cm2; : : : ;Xin�r Cm2 form a basis for m=m2

as a k-vector space, and the lemma shows that A` ' kŒXi1 : : : ;Xin�r �. A homomorphism˛WA`! k of k-algebras is determined by its values ˛.Xi1/; : : : ;˛.Xin�r /, and they can bearbitrarily given. Since the k-linear maps m=m2! k have a similar description, the firstisomorphism is now obvious.

Second isomorphism: To give a k-algebra homomorphism A` ! k is the same as togive an element .a1; : : : ;an/ 2 kn such that f .a1; : : : ;an/D 0 for all f 2 a`, which is thesame as to give an element of TP .V /. 2

Let n be the maximal ideal in Oo (D Am/. According to (1.31), m=m2! n=n2, and sothere is a canonical isomorphism

To.V /'�! Homk-lin.n=n

2;k/:

We adopt this as our definition.

Intrinsic definition of the tangent space 101

DEFINITION 5.14. The tangent space TP .V / at a point P of a variety V is defined to beHomk-linear.nP =n

2P ;k/, where nP the maximal ideal in OP .

The above discussion shows that this agrees with previous definition4 for P D o 2 V �An. The advantage of the present definition is that it obviously depends only on a (small)neighbourhood of P . In particular, it doesn’t depend on an affine embedding of V .

Note that (1.4) implies that the dimension of TP .V / is the minimum number of ele-ments needed to generate nP �OP .

A regular map ˛WV !W sending P to Q defines a local homomorphism OQ!OP ,which induces maps nQ! nP , nQ=n2Q! nP =n

2P , and TP .V /! TQ.W /. The last map

is written .d˛/P . When some open neighbourhoods of P and Q are realized as closedsubvarieties of affine space, then .d˛/P becomes identified with the map defined earlier.

In particular, an f 2 nP is represented by a regular map U ! A1 on a neighbourhoodU of P sending P to 0 and hence defines a linear map .df /P WTP .V /! k. This is justthe map sending a tangent vector (element of Homk-linear.nP =n

2P ;k// to its value at f

mod n2P . Again, in the concrete situation V � Am this agrees with the previous definition.In general, for f 2OP , i.e., for f a germ of a function at P , we define

.df /P D f �f .P / mod n2:

The tangent space at P and the space of differentials at P are dual vector spaces.Consider for example, a2V.a/�An, with a a radical ideal. For f 2 kŒAn�D kŒX1; : : : ;Xn�,

we have (trivial Taylor expansion)

f D f .P /CX

ci .Xi �ai /C terms of degree � 2 in the Xi �ai ;

that is,f �f .P /�

Xci .Xi �ai / mod m2P :

Therefore .df /P can be identified withXci .Xi �ai /D

X @f

@Xi

ˇa.Xi �ai /;

which is how we originally defined the differential.5 The tangent space Ta.V .a// is the zeroset of the equations

.df /P D 0; f 2 a;

and the set f.df /P jTa.V / j f 2 kŒX1; : : : ;Xn�g is the dual space to Ta.V /.

REMARK 5.15. Let E be a finite dimensional vector space over k. Then

To.A.E//'E:4More precisely, define TP .V /DHomk-linear.n=n

2;k/. For V DAm, the elements .dXi /o DXi Cn2 for1 � i � m form a basis for n=n2, and hence form a basis for the space of linear forms on TP .V /. A closedimmersion i WV !Am sending P to omaps TP .V / isomorphically onto the linear subspace of To.Am/ definedby the equations X

1�i�m

�@f

@Xi

�o

.dXi /o D 0; f 2 I.iV /:

5The same discussion applies to any f 2OP . Such an f is of the form gh

with h.a/¤ 0, and has a (notquite so trivial) Taylor expansion of the same form, but with an infinite number of terms, i.e., it lies in the powerseries ring kŒŒX1�a1; : : : ;Xn�an��.

102 5. LOCAL STUDY

Nonsingular points

DEFINITION 5.16. (a) A point P on an algebraic variety V is said to be nonsingular if itlies on a single irreducible component Vi of V , and dimk TP .V /D dimVi ; otherwise thepoint is said to be singular.

(b) A variety is nonsingular if all of its points are nonsingular.(c) The set of singular points of a variety is called its singular locus.

Thus, on an irreducible variety V of dimension d ,

P is nonsingular ” dimk TP .V /D d

” dimk.nP =n2P /D d

” nP can be generated by d functions.

PROPOSITION 5.17. Let V be an irreducible variety of dimension d . If P 2 V is nonsin-gular, then there exist d regular functions f1; : : : ;fd defined in an open neighbourhood Uof P such that P is the only common zero of the fi on U .

PROOF. Let f1; : : : ;fd generate the maximal ideal nP in OP . Then f1; : : : ;fd are alldefined on some open affine neighbourhood U of P , and I claim that P is an irreduciblecomponent of the zero set V.f1; : : : ;fd / of f1; : : : ;fd in U . If not, there will be someirreducible component Z ¤ P of V.f1; : : : ;fd / passing through P . Write Z D V.p/ withp a prime ideal in kŒU �. Because V.p/ � V.f1; : : : ;fd / and because Z contains P and isnot equal to it, we have

.f1; : : : ;fd /� p$mP (ideals in kŒU �/:

On passing to the local ring OP D kŒU �mP , we find (using 1.30) that

.f1; : : : ;fd /� pOP $ nP (ideals in OP /:

This contradicts the assumption that the fi generate nP . Hence P is an irreducible compo-nent of V.f1; : : : ;fd /. On removing the remaining irreducible components of V.f1; : : : ;fd /from U , we obtain an open neighbourhood of P with the required property. 2

THEOREM 5.18. The set of nonsingular points of a variety is dense and open.

PROOF. We have to show that the singular points form a proper closed subset of everyirreducible component of V .

Closed: We can assume that V is affine, say V D V.a/�An. LetP1; : : : ;Pr generate a.Then the set of singular points is the zero set of the ideal generated by the .n�d/� .n�d/minors of the matrix

Jac.P1; : : : ;Pr/.a/D

0BB@@P1@X1

.a/ : : : @P1@Xm

.a/:::

:::@Pr@X1

.a/ : : : @Pr@Xm

.a/

1CCAProper: According to (4.32) and (4.34) there is a nonempty open subset of V isomor-

phic to a nonempty open subset of an irreducible hypersurface in AdC1, and so we may

Nonsingularity and regularity 103

suppose that V is an irreducible hypersurface in AdC1, i.e., that it is the zero set of a singlenonconstant irreducible polynomial F.X1; : : : ;XdC1/. By (2.25), dimV D d . Now theproof is the same as that of (5.3): if @F

@X1is identically zero on V.F /, then @F

@X1must be

divisible by F , and hence be zero. Thus F must be a polynomial in X2; : : :XdC1 (char-acteristic zero) or in Xp1 ;X2; : : : ;XdC1 (characteristic p). Therefore, if all the points of Vare singular, then F is constant (characteristic 0) or a pth power (characteristic p) whichcontradict the hypothesis. 2

COROLLARY 5.19. An irreducible algebraic variety is nonsingular if and only if its tangentspaces TP .V /, P 2 V , all have the same dimension.

PROOF. According to the theorem, the constant dimension of the tangent spaces must bethe dimension of V , and so all points are nonsingular. 2

COROLLARY 5.20. Every algebraic group G is nonsingular.

PROOF. From the theorem we know that there is an open dense subset U of G of non-singular points. For any g 2 G, a 7! ga is an isomorphism G ! G, and so gU consistsof nonsingular points. Clearly G D

SgU . (Alternatively, because G is homogeneous, all

tangent spaces have the same dimension.) 2

In fact, any variety on which a group acts transitively by regular maps will be nonsin-gular.

ASIDE 5.21. Note that, if V is irreducible, then

dimV DminP

dimTP .V /

This formula can be useful in computing the dimension of a variety.

Nonsingularity and regularity

In this section we assume two results that won’t be proved until �9.

5.22. For any irreducible variety V and regular functions f1; : : : ;fr on V , the irreduciblecomponents of V.f1; : : : ;fr/ have dimension � dimV � r (see 9.7).

Note that for polynomials of degree 1 on kn, this is familiar from linear algebra: asystem of r linear equations in n variables either has no solutions (the equations are incon-sistent) or its solutions form an affine space of dimension at least n� r .

5.23. If V is an irreducible variety of dimension d , then the local ring at each point P ofV has dimension d (see 9.6).

Because of (1.30), the height of a prime ideal p of a ring A is the Krull dimension ofAp. Thus (5.23) can be restated as: if V is an irreducible affine variety of dimension d , thenevery maximal ideal in kŒV � has height d .

104 5. LOCAL STUDY

Sketch of proof of (5.23): If V D Ad , then AD kŒX1; : : : ;Xd �, and all maximal idealsin this ring have height d , for example,

.X1�a1; : : : ;Xd �ad /� .X1�a1; : : : ;Xd�1�ad�1/� : : :� .X1�a1/� 0

is a chain of prime ideals of length d that can’t be refined, and there is no longer chain. In thegeneral case, the Noether normalization theorem says that kŒV � is integral over a polynomialring kŒx1; : : : ;xd �, xi 2 kŒV �; then clearly x1; : : : ;xd is a transcendence basis for k.V /, andthe going up and down theorems show that the local rings of kŒV � and kŒx1; : : : ;xd � havethe same dimension.

THEOREM 5.24. Let P be a point on an irreducible variety V . Any generating set for themaximal ideal nP of OP has at least d elements, and there exists a generating set with delements if and only if P is nonsingular.

PROOF. If f1; : : : ;fr generate nP , then the proof of (5.17) shows that P is an irreduciblecomponent of V.f1; : : : ;fr/ in some open neighbourhood U of P . Therefore (5.22) showsthat 0� d � r , and so r � d . The rest of the statement has already been noted. 2

COROLLARY 5.25. A point P on an irreducible variety is nonsingular if and only if OP isregular.

PROOF. This is a restatement of the second part of the theorem. 2

According to CA 17.3, a regular local ring is an integral domain. If P lies on twoirreducible components of a V , then OP is not an integral domain,6 and so OP is notregular. Therefore, the corollary holds also for reducible varieties.

Nonsingularity and normality

An integral domain that is integrally closed in its field of fractions is called a normal ring.

LEMMA 5.26. An integral domain A is normal if and only if Am is normal for all maximalideals m of A.

PROOF. )W If A is integrally closed, then so is S�1A for any multiplicative subset S (notcontaining 0), because if

bnC c1bn�1C�� �C cn D 0; ci 2 S

�1A;

then there is an s 2 S such that sci 2 A for all i , and then

.sb/nC .sc1/.sb/n�1C�� �C sncn D 0;

6Suppose that P lies on the intersection Z1\Z2 of the distinct irreducible components Z1 and Z2. SinceZ1\Z2 is a proper closed subset of Z1, there is an open affine neighbourhood U of P such that U \Z1\Z2is a proper closed subset of U \Z1, and so there is a nonzero regular function f1 on U \Z1 that is zero onU \Z1\Z2. Extend f1 to a neighbourhood of P in Z1[Z2 by setting f1.Q/ D 0 for Q 2 Z2. Then f1defines a nonzero germ of regular function at P . Similarly construct a function f2 that is zero on Z1. Then f1and f2 define nonzero germs of functions at P , but their product is zero.

Etale neighbourhoods 105

demonstrates that sb 2 A, whence b 2 S�1A.(W If c is integral over A, it is integral over each Am, hence in each Am, and AD

TAm

(if c 2TAm, then the set of a 2 A such that ac 2 A is an ideal in A, not contained in any

maximal ideal, and therefore equal to A itself). 2

Thus the following conditions on an irreducible variety V are equivalent:

(a) for all P 2 V , OP is integrally closed;(b) for all irreducible open affines U of V , kŒU � is integrally closed;(c) there is a covering V D

SVi of V by open affines such that kŒVi � is integrally closed

for all i .

An irreducible variety V satisfying these conditions is said to be normal. More generally,an algebraic variety V is said to be normal if OP is normal for all P 2 V . Since, aswe just noted, the local ring at a point lying on two irreducible components can’t be anintegral domain, a normal variety is a disjoint union of irreducible varieties (each of whichis normal).

A regular local noetherian ring is always normal (cf. CA 17.5); conversely, a normallocal integral domain of dimension one is regular. Thus nonsingular varieties are normal,and normal curves are nonsingular. However, a normal surface need not be nonsingular: thecone

X2CY 2�Z2 D 0

is normal, but is singular at the origin — the tangent space at the origin is k3. However, it istrue that the set of singular points on a normal variety V must have dimension � dimV �2.For example, a normal surface can only have isolated singularities — the singular locuscan’t contain a curve.

Etale neighbourhoods

Recall that a regular map ˛WW ! V is said to be etale at a nonsingular point P of W if themap .d˛/P WTP .W /! T˛.P /.V / is an isomorphism.

Let P be a nonsingular point on a variety V of dimension d . A local system of parame-ters at P is a family ff1; : : : ;fd g of germs of regular functions at P generating the maximalideal nP �OP . Equivalent conditions: the images of f1; : : : ;fd in nP =n

2P generate it as a

k-vector space (see 1.4); or .df1/P ; : : : ; .dfd /P is a basis for dual space to TP .V /.

PROPOSITION 5.27. Let ff1; : : : ;fd g be a local system of parameters at a nonsingularpointP of V . Then there is a nonsingular open neighbourhoodU ofP such that f1;f2; : : : ;fdare represented by pairs . Qf1;U /; : : : ; . Qfd ;U / and the map . Qf1; : : : ; Qfd /WU ! Ad is etale.

PROOF. Obviously, the fi are represented by regular functions Qfi defined on a single openneighbourhood U 0 of P , which, because of (5.18), we can choose to be nonsingular. Themap ˛ D . Qf1; : : : ; Qfd /WU 0! Ad is etale at P , because the dual map to .d˛/a is .dXi /o 7!.d Qfi /a. The next lemma then shows that ˛ is etale on an open neighbourhood U of P . 2

LEMMA 5.28. Let W and V be nonsingular varieties. If ˛WW ! V is etale at P , then it isetale at all points in an open neighbourhood of P .

106 5. LOCAL STUDY

PROOF. The hypotheses imply that W and V have the same dimension d , and that theirtangent spaces all have dimension d . We may assume W and V to be affine, say W � Amand V � An, and that ˛ is given by polynomials P1.X1; : : : ;Xm/; : : : ;Pn.X1; : : : ;Xm/.Then .d˛/aWTa.Am/! T˛.a/.An/ is a linear map with matrix

�@Pi@Xj

.a/�

, and ˛ is not etaleat a if and only if the kernel of this map contains a nonzero vector in the subspace Ta.V / ofTa.An/. Let f1; : : : ;fr generate I.W /. Then ˛ is not etale at a if and only if the matrix

@fi@Xj

.a/@Pi@Xj

.a/

!

has rank less than m. This is a polynomial condition on a, and so it fails on a closed subsetof W , which doesn’t contain P . 2

Let V be a nonsingular variety, and let P 2 V . An etale neighbourhood of a point Pof V is pair .Q;� WU ! V / with � an etale map from a nonsingular variety U to V and Qa point of U such that �.Q/D P .

COROLLARY 5.29. Let V be a nonsingular variety of dimension d , and let P 2 V . Thereis an open Zariski neighbourhood U of P and a map � WU ! Ad realizing .P;U / as anetale neighbourhood of .0; : : : ;0/ 2 Ad .

PROOF. This is a restatement of the Proposition. 2

ASIDE 5.30. Note the analogy with the definition of a differentiable manifold: every pointP on nonsingular variety of dimension d has an open neighbourhood that is also a “neigh-bourhood” of the origin in Ad . There is a “topology” on algebraic varieties for which the“open neighbourhoods” of a point are the etale neighbourhoods. Relative to this “topol-ogy”, any two nonsingular varieties are locally isomorphic (this is not true for the Zariskitopology). The “topology” is called the etale topology — see my notes Lectures on EtaleCohomology.

The inverse function theorem

THEOREM 5.31 (INVERSE FUNCTION THEOREM). If a regular map of nonsingular vari-eties 'WV !W is etale at P 2 V , then there exists a commutative diagram

Vopen ���� UP??y' �

??y'0W

etale ���� U'.P /

with UP an open neighbourhood U of P , Uf .P / an etale neighbourhood '.P /, and '0 anisomorphism.

PROOF. According to (5.28), there exists an open neighbourhood U of P such that therestriction 'jU of ' to U is etale. To get the above diagram, we can take UP D U , U'.P /to be the etale neighbourhood 'jU WU !W of '.P /, and '0 to be the identity map. 2

Smooth maps 107

The rank theorem

For vector spaces, the rank theorem says the following: let ˛WV ! W be a linear map ofk-vector spaces of rank r ; then there exist bases for V andW relative to which ˛ has matrix�Ir 0

0 0

�. In other words, there is a commutative diagram

V˛

���������������! W??y� ??y�km

.x1;:::;xm/7!.x1;:::;xr ;0;:::/������������������! kn

A similar result holds locally for differentiable manifolds. In algebraic geometry, there isthe following weaker analogue.

THEOREM 5.32 (RANK THEOREM). Let 'WV !W be a regular map of nonsingular va-rieties of dimensions m and n respectively, and let P 2 V . If rank.TP .'//D n, then thereexists a commutative diagram

UP'jUP

�������������! U'.P /??yetale

??yetale

Am.x1;:::;xm/ 7!.x1;:::;xn/���������������! An

in which UP and U'.P / are open neighbourhoods of P and '.P / respectively and thevertical maps are etale.

PROOF. Choose a local system of parameters g1; : : : ;gn at '.P /, and let f1Dg1ı'; : : : ;fnDgnı'. Then df1; : : : ;dfn are linearly independent forms on TP .V /, and there exist fnC1; : : : ;fmsuch df1; : : : ;dfm is a basis for TP .V /_. Then f1; : : : ;fm is a local system of parametersat P . According to (5.28), there exist open neighbourhoods UP of P and U'.P / of '.P /such that the maps

.f1; : : : ;fm/WUP ! Am

.g1; : : : ;gn/WU'.P /! An

are etale. They give the vertical maps in the above diagram. 2

Smooth maps

DEFINITION 5.33. A regular map 'WV !W of nonsingular varieties is smooth at a pointP of V if .d'/P WTP .V /! T'.P /.W / is surjective; ' is smooth if it is smooth at all pointsof V .

THEOREM 5.34. A map 'WV ! W is smooth at P 2 V if and only if there exist openneighbourhoods UP and U'.P / of P and '.P / respectively such that 'jUP factors into

UPetale��!AdimV�dimW

�U'.P /q�! U'.P /:

108 5. LOCAL STUDY

PROOF. Certainly, if 'jUP factors in this way, it is smooth. Conversely, if ' is smooth atP , then we get a diagram as in the rank theorem. From it we get maps

UP ! Am�An U'.P /! U'.P /:

The first is etale, and the second is the projection of Am�n�U'.P / onto U'.P /. 2

COROLLARY 5.35. Let V and W be nonsingular varieties. If 'WV !W is smooth at P ,then it is smooth on an open neighbourhood of V .

PROOF. In fact, it is smooth on the neighbourhood UP in the theorem. 2

Dual numbers and derivations

In general, if A is a k-algebra andM is an A-module, then a k-derivation is a mapDWA!M such that

(a) D.c/D 0 for all c 2 k;(b) D.f Cg/DD.f /CD.g/;(c) D.fg/D f �DgCf �Dg (Leibniz’s rule).

Note that the conditions imply that D is k-linear (but not A-linear). We write Derk.A;M/

for the space of all k-derivations A!M .For example, the map f 7! .df /P

defD f � f .P / mod n2P is a k-derivation OP !

nP =n2P .

PROPOSITION 5.36. There are canonical isomorphisms

Derk.OP ;k/'! Homk-linear.nP =n

2P ;k/

'! TP .V /:

PROOF. The composite kc 7!c���!OP

f 7!f .P /������! k is the identity map, and so, when regarded

as k-vector space, OP decomposes into

OP D k˚nP ; f $ .f .P /;f �f .P //:

A derivation DWOP ! k is zero on k and on n2P (by Leibniz’s rule). It therefore defines ak-linear map nP =n

2P ! k. Conversely, a k-linear map nP =n

2P ! k defines a derivation by

composition

OPf 7!.df /P�������!nP =n

2P ! k: 2

The ring of dual numbers is kŒ"� D kŒX�=.X2/ where " D X C .X2/. As a k-vectorspace it has a basis f1;"g, and .aCb"/.a0Cb0"/D aa0C .ab0Ca0b/".

PROPOSITION 5.37. The tangent space to V at P is canonically isomorphic to the spaceof local homomorphisms of local k-algebras OP ! kŒ"�:

TP .V /' Hom.OP ;kŒ"�/.

Dual numbers and derivations 109

PROOF. Let ˛WOP ! kŒ"� be a local homomorphism of k-algebras, and write ˛.a/ Da0CD˛.a/". Because ˛ is a homomorphism of k-algebras, a 7! a0 is the quotient mapOP !OP =mD k. We have

˛.ab/D .ab/0CD˛.ab/"; and

˛.a/˛.b/D .a0CD˛.a/"/.b0CD˛.b/"/D a0b0C .a0D˛.b/Cb0D˛.a//":

On comparing these expressions, we see that D˛ satisfies Leibniz’s rule, and therefore is ak-derivation OP ! k. Conversely, all such derivations D arise in this way. 2

Recall (4.42) that for an affine variety V and a k-algebra R (not necessarily an affinek-algebra), we define V.R/ to be Homk-alg.kŒV �;A/. For example, if V D V.a/�An witha radical, then

V.A/D f.a1; : : : ;an/ 2 Anj f .a1; : : : ;an/D 0 all f 2 ag:

Consider an ˛ 2 V.kŒ"�/, i.e., a k-algebra homomorphism ˛WkŒV �! kŒ"�. The compositekŒV �! kŒ"�! k is a point P of V , and

mP D Ker.kŒV �! kŒ"�! k/D ˛�1.."//:

Therefore elements of kŒV � not in mP map to units in kŒ"�, and so ˛ extends to a homomor-phism ˛0WOP ! kŒ"�. By construction, this is a local homomorphism of local k-algebras,and every such homomorphism arises in this way. In this way we get a one-to-one corre-spondence between the local homomorphisms of k-algebras OP ! kŒ"� and the set

fP 0 2 V.kŒ"�/ j P 0 7! P under the map V.kŒ"�/! V.k/g:

This gives us a new interpretation of the tangent space at P .Consider, for example, V DV.a/�An, a a radical ideal in kŒX1; : : : ;Xn�, and let a2V .

In this case, it is possible to show directly that

Ta.V /D fa0 2 V.kŒ"�/ j a0 maps to a under V.kŒ"�/! V.k/g

Note that when we write a polynomial F.X1; : : : ;Xn/ in terms of the variables Xi �ai , weobtain a formula (trivial Taylor formula)

F.X1; : : : ;Xn/D F.a1; : : : ;an/CX @F

@Xi

ˇa.Xi �ai /CR

with R a finite sum of products of at least two terms .Xi �ai /. Now let a 2 kn be a pointon V , and consider the condition for aC"b 2 kŒ"�n to be a point on V . When we substituteai C "bi for Xi in the above formula and take F 2 a, we obtain:

F.a1C "b1; : : : ;anC "bn/D "

�X @F

@Xi

ˇabi

�:

Consequently, .a1C "b1; : : : ;anC "bn/ lies on V if and only if .b1; : : : ;bn/ 2 Ta.V / (orig-inal definition p95).

Geometrically, we can think of a point of V with coordinates in kŒ"� as being a pointof V with coordinates in k (the image of the point under V.kŒ"�/! V.k/) together with a“tangent direction”

110 5. LOCAL STUDY

REMARK 5.38. The description of the tangent space in terms of dual numbers is particu-larly convenient when our variety is given to us in terms of its points functor. For example,let Mn be the set of n�n matrices, and let I be the identity matrix. Write e for I when itis to be regarded as the identity element of GLn.

(a) A matrix I C "A has inverse I � "A in Mn.kŒ"�/, and so lies in GLn.kŒ"�/. There-fore,

Te.GLn/D fI C "A j A 2Mng

'Mn.k/:

(b) Sincedet.I C "A/D I C "trace.A/

(using that "2 D 0),

Te.SLn/D fI C "A j trace.A/D 0g

' fA 2Mn.k/ j trace.A/D 0g:

(c) Assume the characteristic¤ 2, and let On be orthogonal group:

On D fA 2 GLn j Atr�AD I g:

(Atr denotes the transpose ofA). This is the group of matrices preserving the quadratic formX21 C �� � CX

2n . The determinant defines a surjective regular homomorphism detWOn !

f˙1g, whose kernel is defined to be the special orthogonal group SOn. For I C "A 2Mn.kŒ"�/,

.I C "A/tr � .I C "A/D I C "AtrC "A;

and so

Te.On/D Te.SOn/D fI C "A 2Mn.kŒ"�/ j A is skew-symmetricg

' fA 2Mn.k/ j A is skew-symmetricg:

Note that, because an algebraic group is nonsingular, dimTe.G/D dimG — this givesa very convenient way of computing the dimension of an algebraic group.

ASIDE 5.39. On the tangent space Te.GLn/'Mn of GLn, there is a bracket operation

ŒM;N �defDMN �NM

which makes Te.GLn/ into a Lie algebra. For any closed algebraic subgroup G of GLn,Te.G/ is stable under the bracket operation on Te.GLn/ and is a sub-Lie-algebra of Mn,which we denote Lie.G/. The Lie algebra structure on Lie.G/ is independent of the em-bedding ofG into GLn (in fact, it has an intrinsic definition in terms of left invariant deriva-tions), and G 7! Lie.G/ is a functor from the category of linear algebraic groups to that ofLie algebras.

This functor is not fully faithful, for example, any etale homomorphism G! G0 willdefine an isomorphism Lie.G/! Lie.G0/, but it is nevertheless very useful.

Assume k has characteristic zero. A connected algebraic groupG is said to be semisim-ple if it has no closed connected solvable normal subgroup (except feg). Such a group G

Tangent cones 111

may have a finite nontrivial centre Z.G/, and we call two semisimple groups G and G0

locally isomorphic if G=Z.G/�G0=Z.G0/. For example, SLn is semisimple, with centre�n, the set of diagonal matrices diag.�; : : : ; �/, �nD 1, and SLn =�nD PSLn. A Lie algebrais semisimple if it has no commutative ideal (except f0g). One can prove that

G is semisimple ” Lie.G/ is semisimple;

and the map G 7! Lie.G/ defines a one-to-one correspondence between the set of localisomorphism classes of semisimple algebraic groups and the set of isomorphism classes ofLie algebras. The classification of semisimple algebraic groups can be deduced from that ofsemisimple Lie algebras and a study of the finite coverings of semisimple algebraic groups— this is quite similar to the relation between Lie groups and Lie algebras.

Tangent cones

In this section, I assume familiarity with parts of Atiyah and MacDonald 1969, Chapters11, 12.

Let V D V.a/ � km, a D rad.a/, and let P D .0; : : : ;0/ 2 V . Define a� to be theideal generated by the polynomials F� for F 2 a, where F� is the leading form of F (seep93). The geometric tangent cone at P , CP .V / is V.a�/, and the tangent cone is the pair.V .a�/;kŒX1; : : : ;Xn�=a�/. Obviously, CP .V /� TP .V /.

Computing the tangent cone

If a is principal, say a D .F /, then a� D .F�/, but if a D .F1; : : : ;Fr/, then it need notbe true that a� D .F1�; : : : ;Fr�/. Consider for example a D .XY;XZCZ.Y 2 �Z2//.One can show that this is a radical ideal either by asking Macaulay (assuming you believeMacaulay), or by following the method suggested in Cox et al. 1992, p474, problem 3 toshow that it is an intersection of prime ideals. Since

YZ.Y 2�Z2/D Y � .XZCZ.Y 2�Z2//�Z � .XY / 2 a

and is homogeneous, it is in a�, but it is not in the ideal generated by XY , XZ. In fact, a�is the ideal generated by

XY; XZ; YZ.Y 2�Z2/:

This raises the following question: given a set of generators for an ideal a, how do youfind a set of generators for a�? There is an algorithm for this in Cox et al. 1992, p467. Leta be an ideal (not necessarily radical) such that V D V.a/, and assume the origin is in V .Introduce an extra variable T such that T “>” the remaining variables. Make each generatorof a homogeneous by multiplying its monomials by appropriate (small) powers of T , andfind a Grobner basis for the ideal generated by these homogeneous polynomials. RemoveT from the elements of the basis, and then the polynomials you get generate a�.

Intrinsic definition of the tangent cone

Let A be a local ring with maximal ideal n. The associated graded ring is

gr.A/DM

i�0ni=niC1:

Note that if AD Bm and nDmA, then gr.A/DL

mi=miC1 (because of (1.31)).

112 5. LOCAL STUDY

PROPOSITION 5.40. The map kŒX1; : : : ;Xn�=a� ! gr.OP / sending the class of Xi inkŒX1; : : : ;Xn�=a� to the class of Xi in gr.OP / is an isomorphism.

PROOF. Let m be the maximal ideal in kŒX1; : : : ;Xn�=a corresponding to P . Then

gr.OP /DX

mi=miC1

D

X.X1; : : : ;Xn/

i=.X1; : : : ;Xn/iC1Ca\ .X1; : : : ;Xn/

i

D

X.X1; : : : ;Xn/

i=.X1; : : : ;Xn/iC1Cai

where ai is the homogeneous piece of a� of degree i (that is, the subspace of a� consistingof homogeneous polynomials of degree i ). But

.X1; : : : ;Xn/i=.X1; : : : ;Xn/

iC1Cai D i th homogeneous piece of kŒX1; : : : ;Xn�=a�: 2

For a general variety V and P 2 V , we define the geometric tangent cone CP .V / ofV at P to be Spm.gr.OP /red/, where gr.OP /red is the quotient of gr.OP / by its nilradical,and we define the tangent cone to be .CP .V /;gr.OP //.

Recall (Atiyah and MacDonald 1969, 11.21) that dim.A/D dim.gr.A//. Therefore thedimension of the geometric tangent cone at P is the same as the dimension of V (in contrastto the dimension of the tangent space).

Recall (ibid., 11.22) that gr.OP / is a polynomial ring in d variables .d D dimV / if andonly if OP is regular. Therefore, P is nonsingular if and only if gr.OP / is a polynomialring in d variables, in which case CP .V /D TP .V /.

Using tangent cones, we can extend the notion of an etale morphism to singular vari-eties. Obviously, a regular map ˛WV !W induces a homomorphism gr.O˛.P //! gr.OP /.

� The map on the rings kŒX1; : : : ;Xn�=a� defined by a map of algebraic varieties isnot the obvious one, i.e., it is not necessarily induced by the same map on polyno-

mial rings as the original map. To see what it is, it is necessary to use Proposition 5.40, i.e.,it is necessary to work with the rings gr.OP /.

We say that ˛ is etale at P if this is an isomorphism. Note that then there is an iso-morphism of the geometric tangent cones CP .V /! C˛.P /.W /, but this map may be anisomorphism without ˛ being etale at P . Roughly speaking, to be etale at P , we need themap on geometric tangent cones to be an isomorphism and to preserve the “multiplicities”of the components.

It is a fairly elementary result that a local homomorphism of local rings ˛WA! B

induces an isomorphism on the graded rings if and only if it induces an isomorphism on thecompletions (ibid., 10.23). Thus ˛WV !W is etale at P if and only if the map OO˛.P /!OOP is an isomorphism. Hence (5.27) shows that the choice of a local system of parametersf1; : : : ;fd at a nonsingular point P determines an isomorphism OOP ! kŒŒX1; : : : ;Xd ��.

We can rewrite this as follows: let t1; : : : ; td be a local system of parameters at a non-singular point P ; then there is a canonical isomorphism OOP ! kŒŒt1; : : : ; td ��. For f 2 OOP ,the image of f 2 kŒŒt1; : : : ; td �� can be regarded as the Taylor series of f .

For example, let V DA1, and let P be the point a. Then t DX �a is a local parameterat a, OP consists of quotients f .X/D g.X/=h.X/ with h.a/¤ 0, and the coefficients ofthe Taylor expansion

Pn�0an.X�a/

n of f .X/ can be computed as in elementary calculuscourses: an D f .n/.a/=nŠ.

Exercises 113

Exercises

5-1. Find the singular points, and the tangent cones at the singular points, for each of

(a) Y 3�Y 2CX3�X2C3Y 2XC3X2Y C2XY I(b) X4CY 4�X2Y 2 (assume the characteristic is not 2).

5-2. Let V �An be an irreducible affine variety, and letP be a nonsingular point on V . LetH be a hyperplane in An (i.e., the subvariety defined by a linear equation

PaiXi D d with

not all ai zero) passing through P but not containing TP .V /. Show that P is a nonsingularpoint on each irreducible component of V \H on which it lies. (Each irreducible compo-nent has codimension 1 in V — you may assume this.) Give an example with H � TP .V /and P singular on V \H . Must P be singular on V \H if H � TP .V /?

5-3. Let P and Q be points on varieties V and W . Show that

T.P;Q/.V �W /D TP .V /˚TQ.W /:

5-4. For each n, show that there is a curve C and a point P on C such that the tangentspace to C at P has dimension n (hence C can’t be embedded in An�1 ).

5-5. Let I be the n�n identity matrix, and let J be the matrix�0 I

�I 0

�. The symplectic

group Spn is the group of 2n�2n matrices A with determinant 1 such that Atr �J �AD J .(It is the group of matrices fixing a nondegenerate skew-symmetric form.) Find the tangentspace to Spn at its identity element, and also the dimension of Spn.

5-6. Find a regular map ˛WV !W which induces an isomorphism on the geometric tan-gent cones CP .V /! C˛.P /.W / but is not etale at P .

5-7. Show that the cone X2C Y 2 D Z2 is a normal variety, even though the origin issingular (characteristic¤ 2). See p105.

5-8. Let V D V.a/ � An. Suppose that a¤ I.V /, and for a 2 V , let T 0a be the subspaceof Ta.An/ defined by the equations .df /a D 0, f 2 a. Clearly, T 0a � Ta.V /, but need theyalways be different?

CHAPTER 6Projective Varieties

Throughout this chapter, k will be an algebraically closed field. Recall (4.3) that we definedPn to be the set of equivalence classes in knC1r foriging for the relation

.a0; : : : ;an/� .b0; : : : ;bn/ ” .a0; : : : ;an/D c.b0; : : : ;bn/ for some c 2 k�:

Write .a0 W : : : W an/ for the equivalence class of .a0; : : : ;an/, and � for the map

knC1r foriging=�! Pn:

Let Ui be the set of .a0 W : : : W an/ 2 Pn such that ai ¤ 0, and let ui be the bijection

.a0 W : : : W an/ 7!�a0ai; : : : ; an

ai

�WUi 7! An (ai

aiomitted).

In this chapter, we shall define on Pn a (unique) structure of an algebraic variety for whichthese maps become isomorphisms of affine algebraic varieties. A variety isomorphic toa closed subvariety of Pn is called a projective variety, and a variety isomorphic to a lo-cally closed subvariety of Pn is called a quasi-projective variety.1 Every affine variety isquasiprojective, but there are many varieties that are not quasiprojective. We study mor-phisms between quasiprojective varieties.

Projective varieties are important for the same reason compact manifolds are important:results are often simpler when stated for projective varieties, and the “part at infinity” oftenplays a role, even when we would like to ignore it. For example, a famous theorem ofBezout (see 6.34 below) says that a curve of degree m in the projective plane intersects acurve of degree n in exactly mn points (counting multiplicities). For affine curves, one hasonly an inequality.

Algebraic subsets of Pn

A polynomial F.X0; : : : ;Xn/ is said to be homogeneous of degree d if it is a sum of termsai0;:::;inX

i00 � � �X

inn with i0C�� �C in D d ; equivalently,

F.tX0; : : : ; tXn/D tdF.X0; : : : ;Xn/

1A subvariety of an affine variety is said to be quasi-affine. For example, A2r f.0;0/g is quasi-affine butnot affine.

115

116 6. PROJECTIVE VARIETIES

for all t 2 k. Write kŒX0; : : : ;Xn�d for the subspace of kŒX0; : : : ;Xn� of polynomials ofdegree d . Then

kŒX0; : : : ;Xn�DMd�0

kŒX0; : : : ;Xn�d I

that is, each polynomial F can be written uniquely as a sum F DPFd with Fd homoge-

neous of degree d .Let P D .a0 W : : : W an/ 2 Pn. Then P also equals .ca0 W : : : W can/ for any c 2 k�, and

so we can’t speak of the value of a polynomial F.X0; : : : ;Xn/ at P . However, if F ishomogeneous, then F.ca0; : : : ; can/D cdF.a0; : : : ;an/, and so it does make sense to saythat F is zero or not zero at P . An algebraic set in Pn (or projective algebraic set) is theset of common zeros in Pn of some set of homogeneous polynomials.

EXAMPLE 6.1. Consider the projective algebraic subset E of P2 defined by the homoge-neous equation

Y 2Z DX3CaXZ2CbZ3 (14)

whereX3CaXCb is assumed not to have multiple roots. It consists of the points .x W y W 1/on the affine curve E\U2

Y 2 DX3CaXCb;

together with the point “at infinity” .0 W 1 W 0/.Curves defined by equations of the form (14) are called elliptic curves. They can also

be described as the curves of genus one, or as the abelian varieties of dimension one. Sucha curve becomes an algebraic group, with the group law such that P CQCR D 0 if andonly if P , Q, and R lie on a straight line. The zero for the group is the point at infinity.(Without the point at infinity, it is not possible to make E into an algebraic group.)

When a;b 2 Q, we can speak of the zeros of (14) with coordinates in Q. They alsoform a group E.Q/, which Mordell showed to be finitely generated. It is easy to computethe torsion subgroup of E.Q/, but there is at present no known algorithm for computing therank of E.Q/. More precisely, there is an “algorithm” which always works, but which hasnot been proved to terminate after a finite amount of time, at least not in general. There isa very beautiful theory surrounding elliptic curves over Q and other number fields, whoseorigins can be traced back 1,800 years to Diophantus. (See my book on Elliptic Curves forall of this.)

An ideal a � kŒX0; : : : ;Xn� is said to be homogeneous if it contains with any polyno-mial F all the homogeneous components of F , i.e., if

F 2 a H) Fd 2 a, all d:

It is straightforward to check that

˘ an ideal is homogeneous if and only if it is generated by (a finite set of) homogeneouspolynomials;

˘ the radical of a homogeneous ideal is homogeneous;˘ an intersection, product, or sum of homogeneous ideals is homogeneous.

For a homogeneous ideal a, we write V.a/ for the set of common zeros of the homoge-neous polynomials in a. If F1; : : : ;Fr are homogeneous generators for a, then V.a/ is the

Algebraic subsets of Pn 117

set of common zeros of the Fi . Clearly every polynomial in a is zero on every representa-tive of a point in V.a/. We write V aff.a/ for the set of common zeros of a in knC1. It iscone in knC1, i.e., together with any point P it contains the line through P and the origin,and

V.a/D .V aff.a/r .0; : : : ;0//=� :

The sets V.a/ have similar properties to their namesakes in An.

PROPOSITION 6.2. There are the following relations:

(a) a� b) V.a/� V.b/I(b) V.0/D PnI V.a/D∅” rad.a/� .X0; : : : ;Xn/I(c) V.ab/D V.a\b/D V.a/[V.b/I(d) V.

Pai /D

TV.ai /.

PROOF. Statement (a) is obvious. For the second part of (b), note that

V.a/D ; ” V aff.a/� f.0; : : : ;0/g ” rad.a/� .X0; : : : ;Xn/;

by the strong Nullstellensatz (2.11). The remaining statements can be proved directly, orby using the relation between V.a/ and V aff.a/. 2

IfC is a cone in knC1, then I.C / is a homogeneous ideal in kŒX0; : : : ;Xn�: ifF.ca0; : : : ; can/D0 for all c 2 k�, then X

d

Fd .a0; : : : ;an/ � cdD F.ca0; : : : ; can/D 0;

for infinitely many c, and soPFd .a0; : : : ;an/X

d is the zero polynomial. For a subset Sof Pn, we define the affine cone over S in knC1 to be

C D ��1.S/[foriging

and we setI.S/D I.C /.

Note that if S is nonempty and closed, then C is the closure of ��1.S/D ;, and that I.S/is spanned by the homogeneous polynomials in kŒX0; : : : ;Xn� that are zero on S .

PROPOSITION 6.3. The maps V and I define inverse bijections between the set of alge-braic subsets of Pn and the set of proper homogeneous radical ideals of kŒX0; : : : ;Xn�.An algebraic set V in Pn is irreducible if and only if I.V / is prime; in particular, Pn isirreducible.

PROOF. Note that we have bijections

falgebraic subsets of Png fnonempty closed cones in knC1g

fproper homogeneous radical ideals in kŒX0; : : : ;Xn�g

S 7!C

V I

118 6. PROJECTIVE VARIETIES

Here the top map sends S to the affine cone over S , and the maps V and I are in the senseof projective geometry and affine geometry respectively. The composite of any three ofthese maps is the identity map, which proves the first statement because the composite ofthe top map with I is I in the sense of projective geometry. Obviously, V is irreducible ifand only if the closure of ��1.V / is irreducible, which is true if and only if I.V / is a primeideal. 2

Note that .X0; : : : ;Xn/ and kŒX0; : : : ;Xn� are both radical homogeneous ideals, but

V.X0; : : : ;Xn/D ;D V.kŒX0; : : : ;Xn�/

and so the correspondence between irreducible subsets of Pn and radical homogeneousideals is not quite one-to-one.

The Zariski topology on Pn

Proposition 6.2 shows that the projective algebraic sets are the closed sets for a topology onPn. In this section, we verify that it agrees with that defined in the first paragraph of thischapter. For a homogeneous polynomial F , let

D.F /D fP 2 Pn j F.P /¤ 0g:

Then, just as in the affine case, D.F / is open and the sets of this type form a base for thetopology of Pn.

To each polynomial f .X1; : : : ;Xn/, we attach the homogeneous polynomial of the samedegree

f �.X0; : : : ;Xn/DXdeg.f /0 f

�X1X0; : : : ; Xn

X0

�;

and to each homogeneous polynomial F.X0; : : : ;Xn/, we attach the polynomial

F�.X1; : : : ;Xn/D F.1;X1; : : : ;Xn/:

PROPOSITION 6.4. For the topology on Pn just defined, each Ui is open, and when weendow it with the induced topology, the bijection

Ui $ An, .a0 W : : : W 1 W : : : W an/$ .a0; : : : ;ai�1;aiC1; : : : ;an/

becomes a homeomorphism.

PROOF. It suffices to prove this with i D 0. The set U0 DD.X0/, and so it is a basic opensubset in Pn. Clearly, for any homogeneous polynomial F 2 kŒX0; : : : ;Xn�,

D.F.X0; : : : ;Xn//\U0 DD.F.1;X1; : : : ;Xn//DD.F�/

and, for any polynomial f 2 kŒX1; : : : ;Xn�,

D.f /DD.f �/\U0:

Thus, under U0$An, the basic open subsets of An correspond to the intersections with Uiof the basic open subsets of Pn, which proves that the bijection is a homeomorphism. 2

Closed subsets of An and Pn 119

REMARK 6.5. It is possible to use this to give a different proof that Pn is irreducible. Weapply the criterion that a space is irreducible if and only if every nonempty open subset isdense (see p48). Note that each Ui is irreducible, and that Ui \Uj is open and dense ineach of Ui and Uj (as a subset of Ui , it is the set of points .a0 W : : : W 1 W : : : W aj W : : : W an/with aj ¤ 0/. Let U be a nonempty open subset of Pn; then U \Ui is open in Ui . Forsome i , U \Ui is nonempty, and so must meet Ui \Uj . Therefore U meets every Uj , andso is dense in every Uj . It follows that its closure is all of Pn.

Closed subsets of An and Pn

We identify An with U0, and examine the closures in Pn of closed subsets of An. Note that

Pn D AntH1; H1 D V.X0/:

With each ideal a in kŒX1; : : : ;Xn�, we associate the homogeneous ideal a� in kŒX0; : : : ;Xn�generated by ff � j f 2 ag. For a closed subset V of An, set V � D V.a�/ with aD I.V /.

With each homogeneous ideal a in kŒX0;X1; : : : ;Xn], we associate the ideal a� inkŒX1; : : : ;Xn� generated by fF� j F 2 ag. When V is a closed subset of Pn, we set V� DV.a�/ with aD I.V /.

PROPOSITION 6.6. (a) Let V be a closed subset of An. Then V � is the closure of V in Pn,and .V �/� D V . If V D

SVi is the decomposition of V into its irreducible components,

then V � DSV �i is the decomposition of V � into its irreducible components.

(b) Let V be a closed subset of Pn. Then V�D V \An, and if no irreducible componentof V lies in H1 or contains H1, then V� is a proper subset of An, and .V�/� D V .

PROOF. Straightforward. 2

EXAMPLE 6.7. (a) ForV WY 2 DX3CaXCb;

we haveV �WY 2Z DX3CaXZ2CbZ3;

and .V �/� D V .(b) Let V D V.f1; : : : ;fm/; then the closure of V in Pn is the union of the irreducible

components of V.f �1 ; : : : ;f�m/ not contained in H1. For example, let V D V.X1;X21 C

X2/D f.0;0/g; then V.X0X1;X21 CX0X2/ consists of the two points .1W0W0/ (the closureof V ) and .0W0W1/ (which is contained in H1).2

(c) For V DH1 D V.X0/, V� D ;D V.1/ and .V�/� D ;¤ V .

The hyperplane at infinity

It is often convenient to think of Pn as beingAnDU0 with a hyperplane added “at infinity”.More precisely, identify the U0 with An. The complement of U0 in Pn is

H1 D f.0 W a1 W : : : W an/� Png;2Of course, in this case aD .X1;X2/, a� D .X1;X2/, and V � D f.1W0W0/g, and so this example doesn’t

contradict the proposition.

120 6. PROJECTIVE VARIETIES

which can be identified with Pn�1.For example, P1 D A1 tH1 (disjoint union), with H1 consisting of a single point,

and P2 D A2[H1 with H1 a projective line. Consider the line

1CaX1CbX2 D 0

in A2. Its closure in P2 is the line

X0CaX1CbX2 D 0:

This line intersects the line H1 D V.X0/ at the point .0 W �b W a/, which equals .0 W 1 W�a=b/ when b ¤ 0. Note that �a=b is the slope of the line 1C aX1C bX2 D 0, and sothe point at which a line intersects H1 depends only on the slope of the line: parallel linesmeet in one point at infinity. We can think of the projective plane P2 as being the affineplane A2 with one point added at infinity for each direction in A2.

Similarly, we can think of Pn as being An with one point added at infinity for eachdirection in An — being parallel is an equivalence relation on the lines in An, and there isone point at infinity for each equivalence class of lines.

We can also identify An with Un, as in Example 6.1. Note that in this case the pointat infinity on the elliptic curve Y 2 D X3CaXCb is the intersection of the closure of anyvertical line with H1.

Pn is an algebraic variety

For each i , write Oi for the sheaf on Ui � Pn defined by the homeomorphism ui WUi !An.

LEMMA 6.8. Write Uij DUi \Uj ; then Oi jUij DOj jUij . When endowed with this sheafUij is an affine variety; moreover, � .Uij ;Oi / is generated as a k-algebra by the functions.f jUij /.gjUij / with f 2 � .Ui ;Oi /, g 2 � .Uj ;Oj /.

PROOF. It suffices to prove this for .i;j /D .0;1/. All rings occurring in the proof will beidentified with subrings of the field k.X0;X1; : : : ;Xn/.

Recall that

U0 D f.a0 W a1 W : : : W an/ j a0 ¤ 0g; .a0 W a1 W : : : W an/$ .a1a0; a2a0; : : : ; an

a0/ 2 An:

Let kŒX1X0; X2X0; : : : ; Xn

X0� be the subring of k.X0;X1; : : : ;Xn/ generated by the quotients Xi

X0

— it is the polynomial ring in the n symbols X1X0; : : : ; Xn

X0. An element f .X1

X0; : : : ; Xn

X0/ 2

kŒX1X0; : : : ; Xn

X0� defines a map

.a0 W a1 W : : : W an/ 7! f .a1a0; : : : ; an

a0/WU0! k;

and in this way kŒX1X0; X2X0; : : : ; Xn

X0� becomes identified with the ring of regular functions on

U0; and U0 with Spm�kŒX1X0; : : : ; Xn

X0��

.Next consider the open subset of U0;

U01 D f.a0 W : : : W an/ j a0 ¤ 0, a1 ¤ 0g:

Pn is an algebraic variety 121

It is D.X1X0/, and is therefore an affine subvariety of .U0;O0/. The inclusion U01 ,! U0

corresponds to the inclusion of rings kŒX1X0; : : : ; Xn

X0� ,! kŒX1

X0; : : : ; Xn

X0; X0X1�. An element

f .X1X0; : : : ; Xn

X0; X0X1/ of kŒX1

X0; : : : ; Xn

X0; X0X1� defines the function .a0 W : : : W an/ 7!f .a1

a0; : : : ; an

a0; a0a1/

on U01.Similarly,

U1 D f.a0 W a1 W : : : W an/ j a1 ¤ 0g; .a0 W a1 W : : : W an/$ .a0a1; : : : ; an

a1/ 2 An;

and we identifyU1 with Spm�kŒX0X1; X2X0; : : : ; Xn

X1��

. A polynomial f .X0X1; : : : ; Xn

X1/ in kŒX0

X1; : : : ; Xn

X1�

defines the map .a0 W : : : W an/ 7! f .a0a1; : : : ; an

a1/WU1! k.

When regarded as an open subset of U1; U01 DD.X0X1 /, and is therefore an affine sub-variety of .U1;O1/, and the inclusion U01 ,! U1 corresponds to the inclusion of ringskŒX0X1; : : : ; Xn

X1� ,! kŒX0

X1; : : : ; Xn

X1; X1X0�. An element f .X0

X1; : : : ; Xn

X1; X1X0/ of kŒX0

X1; : : : ; Xn

X1; X1X0�

defines the function .a0 W : : : W an/ 7! f .a0a1; : : : ; an

a1; a1a0/ on U01.

The two subrings kŒX1X0; : : : ; Xn

X0; X0X1� and kŒX0

X1; : : : ; Xn

X1; X1X0� of k.X0;X1; : : : ;Xn/ are

equal, and an element of this ring defines the same function on U01 regardless of which ofthe two rings it is considered an element. Therefore, whether we regard U01 as a subvarietyof U0 or of U1 it inherits the same structure as an affine algebraic variety (3.8a). Thisproves the first two assertions, and the third is obvious: kŒX1

X0; : : : ; Xn

X0; X0X1� is generated by

its subrings kŒX1X0; : : : ; Xn

X0� and kŒX0

X1; X2X1; : : : ; Xn

X1�. 2

PROPOSITION 6.9. There is a unique structure of a (separated) algebraic variety on Pn forwhich each Ui is an open affine subvariety of Pn and each map ui is an isomorphism ofalgebraic varieties.

PROOF. Endow each Ui with the structure of an affine algebraic variety for which ui isan isomorphism. Then Pn D

SUi , and the lemma shows that this covering satisfies the

patching condition (4.13), and so Pn has a unique structure of a ringed space for whichUi ,! Pn is a homeomorphism onto an open subset of Pn and OPn jUi DOUi . Moreover,because each Ui is an algebraic variety, this structure makes Pn into an algebraic prevariety.Finally, the lemma shows that Pn satisfies the condition (4.27c) to be separated. 2

EXAMPLE 6.10. Let C be the plane projective curve

C WY 2Z DX3

and assume char.k/¤ 2. For each a 2 k�, there is an automorphism

.x W y W z/ 7! .ax W y W a3z/WC'a�! C:

Patch two copies of C �A1 together along C � .A1 � f0g/ by identifying .P;u/ with.'a.P /;a

�1/, P 2 C , a 2 A1r f0g. One obtains in this way a singular 2-dimensionalvariety that is not quasiprojective (see Hartshorne 1977, Exercise 7.13). It is even complete— see below — and so if it were quasiprojective, it would be projective. It is known thatevery irreducible separated curve is quasiprojective, and every nonsingular complete sur-face is projective, and so this is an example of minimum dimension. In Shafarevich 1994,VI 2.3, there is an example of a nonsingular complete variety of dimension 3 that is notprojective.

122 6. PROJECTIVE VARIETIES

The homogeneous coordinate ring of a subvariety of Pn

Recall (page 50) that we attached to each irreducible variety V a field k.V / with the prop-erty that k.V / is the field of fractions of kŒU � for any open affine U � V . We now describethis field in the case that V D Pn. Recall that kŒU0�D kŒX1X0 ; : : : ;

XnX0�. We regard this as a

subring of k.X0; : : : ;Xn/, and wish to identify the field of fractions of kŒU0� as a subfieldof k.X0; : : : ;Xn/. Any nonzero F 2 kŒU0� can be written

F.X1X0; : : : ; Xn

X0/D

F �.X0; : : : ;Xn/

Xdeg.F /0

with F � homogeneous of degree deg.F /, and it follows that the field of fractions of kŒU0�is

k.U0/D

�G.X0; : : : ;Xn/

H.X0; : : : ;Xn/

ˇG, H homogeneous of the same degree

�[f0g:

Write k.X0; : : : ;Xn/0 for this field (the subscript 0 is short for “subfield of elements ofdegree 0”), so that k.Pn/D k.X0; : : : ;Xn/0. Note that for F D G

Hin k.X0; : : : ;Xn/0;

.a0 W : : : W an/ 7!G.a0; : : : ;an/

H.a0; : : : ;an/WD.H/! k,

is a well-defined function, which is obviously regular (look at its restriction to Ui /.We now extend this discussion to any irreducible projective variety V . Such a V can be

written V D V.p/ with p a homogeneous radical ideal in kŒX0; : : : ;Xn�, and we define thehomogeneous coordinate ring of V (with its given embedding) to be

khomŒV �D kŒX0; : : : ;Xn�=p.

Note that khomŒV � is the ring of regular functions on the affine cone over V ; thereforeits dimension is dim.V /C 1: It depends, not only on V , but on the embedding of V intoPn, i.e., it is not intrinsic to V (see 6.19 below). We say that a nonzero f 2 khomŒV � ishomogeneous of degree d if it can be represented by a homogeneous polynomial F ofdegree d in kŒX0; : : : ;Xn� (we say that 0 is homogeneous of degree 0).

LEMMA 6.11. Each element of khomŒV � can be written uniquely in the form

f D f0C�� �Cfd

with fi homogeneous of degree i .

PROOF. Let F represent f ; then F can be written F D F0C �� �CFd with Fi homoge-neous of degree i , and when reduced modulo p, this gives a decomposition of f of therequired type. Suppose f also has a decomposition f D

Pgi , with gi represented by

the homogeneous polynomial Gi of degree i . Then F �G 2 p, and the homogeneity of pimplies that Fi �Gi D .F �G/i 2 p. Therefore fi D gi . 2

It therefore makes sense to speak of homogeneous elements of kŒV �. For such an ele-ment h, we define D.h/D fP 2 V j h.P /¤ 0g.

Since khomŒV � is an integral domain, we can form its field of fractions khom.V /. Define

khom.V /0 Dn gh2 khom.V /

ˇg and h homogeneous of the same degree

o[f0g:

Regular functions on a projective variety 123

PROPOSITION 6.12. The field of rational functions on V is k.V / defD khom.V /0.

PROOF. Consider V0defD U0\V . As in the case of Pn, we can identify kŒV0� with a subring

of khomŒV �, and then the field of fractions of kŒV0� becomes identified with khom.V /0. 2

Regular functions on a projective variety

Let V be an irreducible projective variety, and let f 2 k.V /. By definition, we can writef D g

hwith g and h homogeneous of the same degree in khomŒV � and h ¤ 0. For any

P D .a0 W : : : W an/ with h.P /¤ 0,

f .P /defDg.a0; : : : ;an/

h.a0; : : : ;an/

is well-defined: if .a0; : : : ;an/ is replaced by .ca0; : : : ; can/, then both the numerator anddenominator are multiplied by cdeg.g/ D cdeg.h/.

We can write f in the form gh

in many different ways,3 but if

f Dg

hDg0

h0(in k.V /0),

thengh0�g0h (in khomŒV �)

and sog.a0; : : : ;an/ �h

0.a0; : : : ;an/D g0.a0; : : : ;an/ �h.a0; : : : ;an/:

Thus, if h0.P /¤ 0, the two representions give the same value for f .P /.

PROPOSITION 6.13. For each f 2 k.V / defD khom.V /0, there is an open subset U of V

where f .P / is defined, and P 7! f .P / is a regular function on U ; every regular functionon an open subset of V arises from a unique element of k.V /.

PROOF. From the above discussion, we see that f defines a regular function on U DSD.h/ where h runs over the denominators of expressions f D g

hwith g and h homo-

geneous of the same degree in khomŒV �.Conversely, let f be a regular function on an open subset U of V , and let P 2 U . Then

P lies in the open affine subvariety V \Ui for some i , and so f coincides with the functiondefined by some fP 2 k.V \Ui /D k.V / on an open neighbourhood of P . If f coincideswith the function defined by fQ 2 k.V / in a neighbourhood of a second pointQ of U , thenfP and fQ define the same function on some open affine U 0, and so fP D fQ as elementsof kŒU 0�� k.V /. This shows that f is the function defined by fP on the whole of U . 2

REMARK 6.14. (a) The elements of k.V /D khom.V /0 should be regarded as the algebraicanalogues of meromorphic functions on a complex manifold; the regular functions on anopen subset U of V are the “meromorphic functions without poles” on U . [In fact, whenk D C, this is more than an analogy: a nonsingular projective algebraic variety over C de-fines a complex manifold, and the meromorphic functions on the manifold are precisely the

3Unless khomŒV � is a unique factorization domain, there will be no preferred representation f D gh

.

124 6. PROJECTIVE VARIETIES

rational functions on the variety. For example, the meromorphic functions on the Riemannsphere are the rational functions in z.]

(b) We shall see presently (6.21) that, for any nonzero homogeneous h 2 khomŒV �,D.h/is an open affine subset of V . The ring of regular functions on it is

kŒD.h/�D fg=hm j g homogeneous of degree mdeg.h/g[f0g:

We shall also see that the ring of regular functions on V itself is just k, i.e., any regularfunction on an irreducible (connected will do) projective variety is constant. However, if Uis an open nonaffine subset of V , then the ring � .U;OV / of regular functions can be almostanything — it needn’t even be a finitely generated k-algebra!

Morphisms from projective varieties

We describe the morphisms from a projective variety to another variety.

PROPOSITION 6.15. The map

� WAnC1r foriging ! Pn, .a0; : : : ;an/ 7! .a0 W : : : W an/

is an open morphism of algebraic varieties. A map ˛WPn! V with V a prevariety is regularif and only if ˛ ı� is regular.

PROOF. The restriction of � to D.Xi / is the projection

.a0; : : : ;an/ 7! .a0aiW : : : W an

ai/WknC1rV.Xi /! Ui ;

which is the regular map of affine varieties corresponding to the map of k-algebras

khX0Xi; : : : ; Xn

Xi

i! kŒX0; : : : ;Xn�ŒX

�1i �:

(In the first algebra XjXi

is to be thought of as a single symbol.) It now follows from (4.4)that � is regular.

Let U be an open subset of knC1r foriging, and let U 0 be the union of all the linesthrough the origin that meet U , that is, U 0 D ��1�.U /. Then U 0 is again open in knC1rforiging, because U 0D

ScU , c 2 k�, and x 7! cx is an automorphism of knC1rforiging.

The complement Z of U 0 in knC1r foriging is a closed cone, and the proof of (6.3) showsthat its image is closed in Pn; but �.U / is the complement of �.Z/. Thus � sends opensets to open sets.

The rest of the proof is straightforward. 2

Thus, the regular maps Pn! V are just the regular maps AnC1r foriging! V factor-ing through Pn (as maps of sets).

REMARK 6.16. Consider polynomials F0.X0; : : : ;Xm/; : : : ;Fn.X0; : : : ;Xm/ of the samedegree. The map

.a0 W : : : W am/ 7! .F0.a0; : : : ;am/ W : : : W Fn.a0; : : : ;am//

Examples of regular maps of projective varieties 125

obviously defines a regular map to Pn on the open subset of Pm where not all Fi vanish,that is, on the set

SD.Fi /D PnrV.F1; : : : ;Fn/. Its restriction to any subvariety V of Pm

will also be regular. It may be possible to extend the map to a larger set by representingit by different polynomials. Conversely, every such map arises in this way, at least locally.More precisely, there is the following result.

PROPOSITION 6.17. Let V D V.a/ � Pm and W D V.b/ � Pn. A map 'WV ! W isregular if and only if, for every P 2 V , there exist polynomials

F0.X0; : : : ;Xm/; : : : ;Fn.X0; : : : ;Xm/;

homogeneous of the same degree, such that

' ..b0 W : : : W bn//D .F0.b0; : : : ;bm/ W : : : W Fn.b0; : : : ;bm//

for all points .b0 W : : : W bm/ in some neighbourhood of P in V.a/.

PROOF. Straightforward. 2

EXAMPLE 6.18. We prove that the circle X2CY 2 D Z2 is isomorphic to P1. This equa-tion can be rewritten .X C iY /.X � iY / D Z2, and so, after a change of variables, theequation of the circle becomes C WXZ D Y 2. Define

'WP1! C , .a W b/ 7! .a2 W ab W b2/:

For the inverse, define

WC ! P1 by�.a W b W c/ 7! .a W b/ if a¤ 0.a W b W c/ 7! .b W c/ if b ¤ 0

:

Note that,

a¤ 0¤ b; ac D b2 H)c

bDb

a

and so the two maps agree on the set where they are both defined. Clearly, both ' and are regular, and one checks directly that they are inverse.

Examples of regular maps of projective varieties

We list some of the classic maps.

EXAMPLE 6.19. Let L DPciXi be a nonzero linear form in nC 1 variables. Then the

map

.a0 W : : : W an/ 7!

�a0

L.a/; : : : ;

an

L.a/

�is a bijection of D.L/ � Pn onto the hyperplane L.X0;X1; : : : ;Xn/ D 1 of AnC1, withinverse

.a0; : : : ;an/ 7! .a0 W : : : W an/:

Both maps are regular — for example, the components of the first map are the regularfunctions XjP

ciXi. As V.L� 1/ is affine, so also is D.L/, and its ring of regular functions

126 6. PROJECTIVE VARIETIES

is kΠX0PciXi

; : : : ; XnPciXi

�: In this ring, each quotient XjPciXi

is to be thought of as a single

symbol, andPcj

XjPciXiD 1; thus it is a polynomial ring in n symbols; any one symbol

XjPciXi

for which cj ¤ 0 can be omitted (see Lemma 5.12).For a fixed P D .a0W : : : Wan/ 2 Pn, the set of cD .c0W : : : W cn/ such that

Lc.P /defD

Xciai ¤ 0

is a nonempty open subset of Pn (n > 0). Therefore, for any finite set S of points of Pn,

fc 2 Pn j S �D.Lc/g

is a nonempty open subset of Pn (because Pn is irreducible). In particular, S is containedin an open affine subset D.Lc/ of Pn. Moreover, if S � V where V is a closed subvarietyof Pn, then S � V \D.Lc/: any finite set of points of a projective variety is contained inan open affine subvariety.

EXAMPLE 6.20. (The Veronese map.) Let

I D f.i0; : : : ; in/ 2 NnC1 jX

ij Dmg:

Note that I indexes the monomials of degreem in nC1 variables. It has�mCnm

�elements4.

Write �n;m D�mCnm

�� 1, and consider the projective space P�n;m whose coordinates are

indexed by I ; thus a point of P�n;m can be written .: : : W bi0:::in W : : :/. The Veronese mappingis defined to be

vWPn! P�n;m , .a0 W : : : W an/ 7! .: : : W bi0:::in W : : :/; bi0:::in D ai00 : : :a

inn :

In other words, the Veronese mapping sends an nC1-tuple .a0W : : : W an/ to the set of mono-mials in the ai of degre m. For example, when nD 1 and mD 2, the Veronese map is

P1! P2, .a0 W a1/ 7! .a20 W a0a1 W a21/:

Its image is the curve �.P1/ WX0X2 DX21 , and the map

.b2;0 W b1;1 W b0;2/ 7!

�.b2;0 W b1;1/ if b2;0 ¤ 1.b1;1 W b0;2/ if b0;2 ¤ 0:

is an inverse �.P1/! P1. (Cf. Example 6.19.) 5

4This can be proved by induction on mC n. If m D 0 D n, then�00

�D 1, which is correct. A general

homogeneous polynomial of degree m can be written uniquely as

F.X0;X1; : : : ;Xn/D F1.X1; : : : ;Xn/CX0F2.X0;X1; : : : ;Xn/

with F1 homogeneous of degree m and F2 homogeneous of degree m�1. But�mCnn

�D�mCn�1m

�C�mCn�1m�1

�because they are the coefficients of Xm in

.XC1/mCn D .XC1/.XC1/mCn�1;

and this proves the induction.5Note that, although P1 and �.P1/ are isomorphic, their homogeneous coordinate rings are not. In fact

khomŒP1�D kŒX0;X1�, which is the affine coordinate ring of the smooth variety A2, whereas khomŒ�.P1/�DkŒX0;X1;X2�=.X0X2�X

21 / which is the affine coordinate ring of the singular variety X0X2�X21 .

Examples of regular maps of projective varieties 127

When nD 1 and m is general, the Veronese map is

P1! Pm, .a0 W a1/ 7! .am0 W am�10 a1 W : : : W a

m1 /:

I claim that, in the general case, the image of � is a closed subset of P�n;m and that �defines an isomorphism of projective varieties �WPn! �.Pn/.

First note that the map has the following interpretation: if we regard the coordinates aiof a point P of Pn as being the coefficients of a linear form LD

PaiXi (well-defined up

to multiplication by nonzero scalar), then the coordinates of �.P / are the coefficients of thehomogeneous polynomial Lm with the binomial coefficients omitted.

As L¤ 0) Lm ¤ 0, the map � is defined on the whole of Pn, that is,

.a0; : : : ;an/¤ .0; : : : ;0/) .: : : ;bi0:::in ; : : :/¤ .0; : : : ;0/:

Moreover, L1 ¤ cL2) Lm1 ¤ cLm2 , because kŒX0; : : : ;Xn� is a unique factorization do-

main, and so � is injective. It is clear from its definition that � is regular.We shall see later in this chapter that the image of any projective variety under a regular

map is closed, but in this case we can prove directly that �.Pn/ is defined by the system ofequations:

bi0:::inbj0:::jn D bk0:::knb`0:::`n ; ihCjh D khC`h, all h (*).

Obviously Pn maps into the algebraic set defined by these equations. Conversely, let

Vi D f.: : : : W bi0:::in W : : :/ j b0:::0m0:::0 ¤ 0g:

Then �.Ui / � Vi and ��1.Vi / D Ui . It is possible to write down a regular map Vi ! Uiinverse to �jUi : for example, define V0! Pn to be

.: : : W bi0:::in W : : :/ 7! .bm;0;:::;0 W bm�1;1;0;:::;0 W bm�1;0;1;0;:::;0 W : : : W bm�1;0;:::;0;1/:

Finally, one checks that �.Pn/�SVi .

For any closed variety W � Pn, �jW is an isomorphism of W onto a closed subvariety�.W / of �.Pn/� P�n;m .

REMARK 6.21. The Veronese mapping has a very important property. If F is a nonzerohomogeneous form of degreem� 1, then V.F /� Pn is called a hypersurface of degreemand V.F /\W is called a hypersurface section of the projective variety W . When mD 1,“surface” is replaced by “plane”.

Now let H be the hypersurface in Pn of degree mXai0:::inX

i00 � � �X

inn D 0,

and let L be the hyperplane in P�n;m defined byXai0:::inXi0:::in :

Then �.H/D �.Pn/\L, i.e.,

H.a/D 0 ” L.�.a//D 0:

128 6. PROJECTIVE VARIETIES

Thus for any closed subvariety W of Pn, � defines an isomorphism of the hypersurfacesectionW \H of V onto the hyperplane section �.W /\L of �.W /. This observation oftenallows one to reduce questions about hypersurface sections to questions about hyperplanesections.

As one example of this, note that � maps the complement of a hypersurface section ofW isomorphically onto the complement of a hyperplane section of �.W /, which we knowto be affine. Thus the complement of any hypersurface section of a projective variety is anaffine variety—we have proved the statement in (6.14b).

EXAMPLE 6.22. An element AD .aij / of GLnC1 defines an automorphism of Pn:

.x0 W : : : W xn/ 7! .: : : WPaijxj W : : :/I

clearly it is a regular map, and the inverse matrix gives the inverse map. Scalar matrices actas the identity map.

Let PGLnC1 D GLnC1 =k�I , where I is the identity matrix, that is, PGLnC1 is thequotient of GLnC1 by its centre. Then PGLnC1 is the complement in P.nC1/2�1 of thehypersurface det.Xij /D 0, and so it is an affine variety with ring of regular functions

kŒPGLnC1�D fF.: : : ;Xij ; : : :/=det.Xij /m j deg.F /Dm � .nC1/g[f0g:

It is an affine algebraic group.The homomorphism PGLnC1!Aut.Pn/ is obviously injective. We sketch a proof that

it is surjective.6 Consider a hypersurface

H WF.X0; : : : ;Xn/D 0

in Pn and a lineLD f.ta0 W : : : W tan/ j t 2 kg

in Pn. The points of H \L are given by the solutions of

F.ta0; : : : ; tan/D 0,

which is a polynomial of degree � deg.F / in t unless L�H . Therefore, H \L contains� deg.F / points, and it is not hard to show that for a fixed H and most L it will containexactly deg.F / points. Thus, the hyperplanes are exactly the closed subvarieties H of Pnsuch that

(a) dim.H/D n�1;(b) #.H \L/D 1 for all lines L not contained in H .

These are geometric conditions, and so any automorphism of Pn must map hyperplanes tohyperplanes. But on an open subset of Pn, such an automorphism takes the form

.b0 W : : : W bn/ 7! .F0.b0; : : : ;bn/ W : : : W Fn.b0; : : : ;bn//

where the Fi are homogeneous of the same degree d (see 6.17). Such a map will takehyperplanes to hyperplanes if only if d D 1.

6This is related to the fundamental theorem of projective geometry — see E. Artin, Geometric Algebra,Interscience, 1957, Theorem 2.26.

Examples of regular maps of projective varieties 129

EXAMPLE 6.23. (The Segre map.) This is the mapping

..a0 W : : : W am/; .b0 W : : : W bn// 7! ..: : : W aibj W : : ://WPm�Pn! PmnCmCn:

The index set for PmnCmCn is f.i;j / j 0 � i �m; 0 � j � ng. Note that if we interpretthe tuples on the left as being the coefficients of two linear forms L1 D

PaiXi and L2 DP

bjYj , then the image of the pair is the set of coefficients of the homogeneous form ofdegree 2, L1L2. From this observation, it is obvious that the map is defined on the whole ofPm�Pn .L1¤ 0¤L2)L1L2¤ 0/ and is injective. On any subset of the form Ui �Uj itis defined by polynomials, and so it is regular. Again one can show that it is an isomorphismonto its image, which is the closed subset of PmnCmCn defined by the equations

wijwkl �wilwkj D 0

– see Shafarevich 1994, I 5.1. For example, the map

..a0 W a1/; .b0 W b1// 7! .a0b0 W a0b1 W a1b0 W a1b1/WP1�P1! P3

has image the hypersurfaceH W WZ DXY:

The map.w W x W y W z/ 7! ..w W y/;.w W x//

is an inverse on the set where it is defined. [Incidentally, P1 � P1 is not isomorphic toP2, because in the first variety there are closed curves, e.g., two vertical lines, that don’tintersect.]

If V and W are closed subvarieties of Pm and Pn, then the Segre map sends V �Wisomorphically onto a closed subvariety of PmnCmCn. Thus products of projective varietiesare projective.

There is an explicit description of the topology on Pm�Pn W the closed sets are the setsof common solutions of families of equations

F.X0; : : : ;XmIY0; : : : ;Yn/D 0

with F separately homogeneous in the X ’s and in the Y ’s.

EXAMPLE 6.24. Let L1; : : : ;Ln�d be linearly independent linear forms in nC1 variables.Their zero setE in knC1 has dimension dC1, and so their zero set in Pn is a d -dimensionallinear space. Define � WPn�E! Pn�d�1 by �.a/D .L1.a/ W : : : W Ln�d .a//; such a mapis called a projection with centre E. If V is a closed subvariety disjoint from E, then �defines a regular map V ! Pn�d�1. More generally, if F1; : : : ;Fr are homogeneous formsof the same degree, and Z D V.F1; : : : ;Fr/, then a 7! .F1.a/ W : : : W Fr.a// is a morphismPn�Z! Pr�1.

By carefully choosing the centre E, it is possible to linearly project any smooth curvein Pn isomorphically onto a curve in P3, and nonisomorphically (but bijectively on an opensubset) onto a curve in P2 with only nodes as singularities.7 For example, suppose we have

7A nonsingular curve of degree d in P2 has genus .d�1/.d�2/2 . Thus, if g is not of this form, a curve ofgenus g can’t be realized as a nonsingular curve in P2.

130 6. PROJECTIVE VARIETIES

a nonsingular curve C in P3. To project to P2 we need three linear forms L0, L1, L2 andthe centre of the projection is the point P0 where all forms are zero. We can think of themap as projecting from the centre P0 onto some (projective) plane by sending the point Pto the point where P0P intersects the plane. To project C to a curve with only ordinarynodes as singularities, one needs to choose P0 so that it doesn’t lie on any tangent to C , anytrisecant (line crossing the curve in 3 points), or any chord at whose extremities the tangentsare coplanar. See for example Samuel, P., Lectures on Old and New Results on AlgebraicCurves, Tata Notes, 1966.

Projecting a nonsingular variety in Pn to a lower dimensional projective space usuallyintroduces singularities; Hironaka proved that every singular variety arises in this way incharacteristic zero.

PROPOSITION 6.25. Every finite set S of points of a quasiprojective variety V is containedin an open affine subset of V .

PROOF. Regard V as a subvariety of Pn, let NV be the closure of V in Pn, and letZD NV rV .Because S \Z D ;, for each P 2 S there exists a homogeneous polynomial FP 2 I.Z/such that FP .P /¤ 0. We may suppose that the FP ’s have the same degree. An elementaryargument shows that some linear combination F of the FP , P 2 S , is nonzero at each P .Then F is zero on Z, and so NV \D.F / is an open affine of V , but F is nonzero at each P ,and so NV \D.F / contains S . 2

Projective space without coordinates

Let E be a vector space over k of dimension n. The set P.E/ of lines through zero in Ehas a natural structure of an algebraic variety: the choice of a basis for E defines a bijectionP.E/! Pn, and the inherited structure of an algebraic variety on P.E/ is independent ofthe choice of the basis (because the bijections defined by two different bases differ by an au-tomorphism of Pn). Note that in contrast to Pn, which has nC1 distinguished hyperplanes,namely, X0 D 0; : : : ;Xn D 0, no hyperplane in P.E/ is distinguished.

Grassmann varieties

Let E be a vector space over k of dimension n, and let Gd .E/ be the set of d -dimensionalsubspaces of E. When d D 0 or n, Gd .E/ has a single element, and so from now on weassume that 0 < d < n. Fix a basis for E, and let S 2 Gd .E/. The choice of a basis for Sthen determines a d �n matrix A.S/ whose rows are the coordinates of the basis elements.Changing the basis for S multipliesA.S/ on the left by an invertible d �d matrix. Thus, thefamily of d �d minors of A.S/ is determined up to multiplication by a nonzero constant,

and so defines a point P.S/ in P�nd

��1.

PROPOSITION 6.26. The map S 7! P.S/WGd .E/! P�nd

��1 is injective, with image a

closed subset of P�nd

��1.

We give the proof below. The maps P defined by different bases of E differ by an

automorphism of P�nd

��1, and so the statement is independent of the choice of the basis

Grassmann varieties 131

— later (6.31) we shall give a “coordinate-free description” of the map. The map realizesGd .E/ as a projective algebraic variety called the Grassmann variety of d -dimensionalsubspaces of E.

EXAMPLE 6.27. The affine cone over a line in P3 is a two-dimensional subspace of k4.Thus, G2.k4/ can be identified with the set of lines in P3. Let L be a line in P3, and letxD .x0 W x1 W x2 W x3/ and yD .y0 W y1 W y2 W y3/ be distinct points on L. Then

P.L/D .p01 W p02 W p03 W p12 W p13 W p23/ 2 P5; pijdefD

ˇxi xjyi yj

ˇ;

depends only on L. The map L 7! P.L/ is a bijection from G2.k4/ onto the quadric

˘ WX01X23�X02X13CX03X12 D 0

in P5. For a direct elementary proof of this, see (10.20, 10.21) below.

REMARK 6.28. Let S 0 be a subspace of E of complementary dimension n� d , and letGd .E/S 0 be the set of S 2 Gd .V / such that S \S 0 D f0g. Fix an S0 2 Gd .E/S 0 , so thatE D S0˚S

0. For any S 2Gd .V /S 0 , the projection S! S0 given by this decomposition isan isomorphism, and so S is the graph of a homomorphism S0! S 0:

s 7! s0 ” .s; s0/ 2 S:

Conversely, the graph of any homomorphism S0! S 0 lies in Gd .V /S 0 . Thus,

Gd .V /S 0 � Hom.S0;S 0/� Hom.E=S 0;S 0/: (15)

The isomorphism Gd .V /S 0 � Hom.E=S 0;S 0/ depends on the choice of S0 — it is theelement of Gd .V /S 0 corresponding to 0 2 Hom.E=S 0;S 0/. The decomposition E D S0˚S 0 gives a decomposition End.E/D

�End.S0/ Hom.S 0;S0/

Hom.S0;S 0/ End.S 0/

�, and the bijections (15) show

that the group�

1 0Hom.S0;S 0/ 1

�acts simply transitively on Gd .E/S 0 .

REMARK 6.29. The bijection (15) identifiesGd .E/S 0 with the affine varietyA.Hom.S0;S 0//defined by the vector space Hom.S0;S 0/ (cf. p67). Therefore, the tangent space to Gd .E/at S0,

TS0.Gd .E//' Hom.S0;S 0/' Hom.S0;E=S0/: (16)

Since the dimension of this space doesn’t depend on the choice of S0, this shows thatGd .E/ is nonsingular (5.19).

REMARK 6.30. Let B be the set of all bases of E. The choice of a basis for E identi-fies B with GLn, which is the principal open subset of An2 where det ¤ 0. In particu-lar, B has a natural structure as an irreducible algebraic variety. The map .e1; : : : ; en/ 7!he1; : : : ; ed iWB!Gd .E/ is a surjective regular map, and so Gd .E/ is also irreducible.

REMARK 6.31. The exterior algebraVED

Ld�0

VdE ofE is the quotient of the tensor

algebra by the ideal generated by all vectors e˝e, e 2E. The elements ofVd

E are called(exterior) d -vectors:The exterior algebra ofE is a finite-dimensional graded algebra over k

132 6. PROJECTIVE VARIETIES

withV0

E D k,V1

E D E; if e1; : : : ; en form an ordered basis for V , then the�nd

�wedge

products ei1 ^ : : :^eid (i1 < � � �< id ) form an ordered basis forVd

E. In particular,Vn

E

has dimension 1. For a subspace S of E of dimension d ,Vd

S is the one-dimensionalsubspace of

VdE spanned by e1^ : : :^ ed for any basis e1; : : : ; ed of S . Thus, there is a

well-defined map

S 7!^d

S WGd .E/! P.^d

E/ (17)

which the choice of a basis forE identifies with S 7!P.S/. Note that the subspace spannedby e1; : : : ; en can be recovered from the line through e1^ : : :^ ed as the space of vectors vsuch that v^ e1^ : : :^ ed D 0 (cf. 6.32 below).

First proof of Proposition 6.26. Fix a basis e1; : : : ; en of E, and let S0D he1; : : : ; ed i

and S 0 D hedC1; : : : ; eni. Order the coordinates in P�nd

��1 so that

P.S/D .a0W : : : W aij W : : : W : : :/

where a0 is the left-most d � d minor of A.S/, and aij , 1 � i � d , d < j � n, is theminor obtained from the left-most d �d minor by replacing the i th column with the j th

column. Let U0 be the (“typical”) standard open subset of P�nd

��1 consisting of the points

with nonzero zeroth coordinate. Clearly,8 P.S/ 2U0 if and only if S 2Gd .E/S 0 . We shallprove the proposition by showing that P WGd .E/S 0 ! U0 is injective with closed image.

For S 2Gd .E/S 0 , the projection S ! S0 is bijective. For each i , 1� i � d , let

e0i D ei CPd<j�naij ej (18)

denote the unique element of S projecting to ei . Then e01; : : : ; e0d

is a basis for S . Con-versely, for any .aij / 2 kd.n�d/, the e0i ’s defined by (18) span an S 2Gd .E/S 0 and projectto the ei ’s. Therefore, S $ .aij / gives a one-to-one correspondence Gd .E/S 0 $ kd.n�d/

(this is a restatement of (15) in terms of matrices).Now, if S $ .aij /, then

P.S/D .1 W : : : W aij W : : : W : : : W fk.aij /W : : :/

where fk.aij / is a polynomial in the aij whose coefficients are independent of S . Thus,P.S/ determines .aij / and hence also S . Moreover, the image of P WGd .E/S 0! U0 is thegraph of the regular map

.: : : ;aij ; : : :/ 7! .: : : ;fk.aij /; : : :/WAd.n�d/! A�nd

��d.n�d/�1

;

which is closed (4.26).

Second proof of Proposition 6.26. An exterior d -vector v is said to be pure (or de-composable) if there exist vectors e1; : : : ; ed 2 V such that v D e1^ : : :^ ed . According to(6.31), the image of Gd .E/ in P.

VdE/ consists of the lines through the pure d -vectors.

8If e 2 S 0 \S is nonzero, we may choose it to be part of the basis for S , and then the left-most d � dsubmatrix of A.S/ has a row of zeros. Conversely, if the left-most d �d submatrix is singular, we can changethe basis for S so that it has a row of zeros; then the basis element corresponding to the zero row lies in S 0\S .

Grassmann varieties 133

LEMMA 6.32. Let w be a nonzero d -vector and let

M.w/D fv 2E j v^w D 0gI

then dimkM.w/� d , with equality if and only if w is pure.

PROOF. Let e1; : : : ; em be a basis of M.w/, and extend it to a basis e1; : : : ; em; : : : ; en of V .Write

w DX

1�i1<:::<id

ai1:::id ei1 ^ : : :^ eid ; ai1:::id 2 k.

If there is a nonzero term in this sum in which ej does not occur, then ej ^w¤ 0. Therefore,each nonzero term in the sum is of the form ae1^ : : :^ em^ : : :. It follows that m� d , andmD d if and only if w D ae1^ : : :^ ed with a¤ 0. 2

For a nonzero d -vector w, let Œw� denote the line through w. The lemma shows thatŒw� 2 Gd .E/ if and only if the linear map v 7! v^wWE 7!

VdC1E has rank � n�d (in

which case the rank is n�d ). Thus Gd .E/ is defined by the vanishing of the minors oforder n�d C1 of this map. 9

Flag varieties

The discussion in the last subsection extends easily to chains of subspaces. Let d D.d1; : : : ;dr/ be a sequence of integers with 0 < d1 < � � � < dr < n, and let Gd.E/ be theset of flags

F W E �E1 � �� � �Er � 0 (19)

with Ei a subspace of E of dimension di . The map

Gd.E/F 7!.V i /������!

QiGdi .E/�

QiP.VdiE/

realizes Gd.E/ as a closed subset10 QiGdi .E/, and so it is a projective variety, called a

flag variety: The tangent space to Gd.E/ at the flag F consists of the families of homomor-phisms

'i WEi ! V=Ei ; 1� i � r; (20)9In more detail, the map

w 7! .v 7! v^w/W^d

E! Homk.E;^dC1

E/

is injective and linear, and so defines an injective regular map

P.^d

E/ ,! P.Homk.E;^dC1

E//:

The condition rank� n�d defines a closed subsetW of P.Homk.E;VdC1E// (once a basis has been chosen

for E, the condition becomes the vanishing of the minors of order n�d C 1 of a linear map E!VdC1E),

andGd .E/D P.

VdE/\W:10For example, if ui is a pure di -vector and uiC1 is a pure diC1-vector, then it follows from (6.32) that

M.ui /�M.uiC1/ if and only if the map

v 7! .v^ui ;v^uiC1/WV !^diC1

V ˚^diC1C1

V

has rank � n�di (in which case it has rank n�di ). Thus, Gd.V / is defined by the vanishing of many minors.

134 6. PROJECTIVE VARIETIES

that are compatible in the sense that

'i jEiC1 � 'iC1 mod EiC1:

ASIDE 6.33. A basis e1; : : : ; en forE is adapted to the flagF if it contains a basis e1; : : : ; ejifor each Ei . Clearly, every flag admits such a basis, and the basis then determines the flag.As in (6.30), this implies that Gd.E/ is irreducible. Because GL.E/ acts transitively onthe set of bases for E, it acts transitively on Gd.E/. For a flag F , the subgroup P.F /stabilizing F is an algebraic subgroup of GL.E/, and the map

g 7! gF0WGL.E/=P.F0/!Gd.E/

is an isomorphism of algebraic varieties. Because Gd.E/ is projective, this shows thatP.F0/ is a parabolic subgroup of GL.V /.

Bezout’s theorem

Let V be a hypersurface in Pn (that is, a closed subvariety of dimension n� 1). For sucha variety, I.V / D .F.X0; : : : ;Xn// with F a homogenous polynomial without repeatedfactors. We define the degree of V to be the degree of F .

The next theorem is one of the oldest, and most famous, in algebraic geometry.

THEOREM 6.34. Let C and D be curves in P2 of degrees m and n respectively. If C andD have no irreducible component in common, then they intersect in exactly mn points,counted with appropriate multiplicities.

PROOF. Decompose C and D into their irreducible components. Clearly it suffices toprove the theorem for each irreducible component of C and each irreducible component ofD. We can therefore assume that C and D are themselves irreducible.

We know from (2.26) that C \D is of dimension zero, and so is finite. After a changeof variables, we can assume that a¤ 0 for all points .a W b W c/ 2 C \D.

Let F.X;Y;Z/ and G.X;Y;Z/ be the polynomials defining C and D, and write

F D s0ZmC s1Z

m�1C�� �C sm; G D t0Z

nC t1Z

n�1C�� �C tn

with si and tj polynomials inX and Y of degrees i and j respectively. Clearly sm¤ 0¤ tn,for otherwise F and G would have Z as a common factor. Let R be the resultant of F andG, regarded as polynomials in Z. It is a homogeneous polynomial of degree mn in X andY , or else it is identically zero. If the latter occurs, then for every .a;b/ 2 k2, F.a;b;Z/and G.a;b;Z/ have a common zero, which contradicts the finiteness of C \D. Thus Ris a nonzero polynomial of degree mn. Write R.X;Y / D XmnR�.YX / where R�.T / is apolynomial of degree �mn in T D Y

X.

Suppose first that degR� Dmn, and let ˛1; : : : ;˛mn be the roots of R� (some of themmay be multiple). Each such root can be written ˛i D bi

ai, and R.ai ;bi /D 0. According to

(7.12) this means that the polynomials F.ai ;bi ;Z/ and G.ai ;bi ;Z/ have a common rootci . Thus .ai W bi W ci / is a point on C \D, and conversely, if .a W b W c/ is a point on C \D(so a ¤ 0/, then b

ais a root of R�.T /. Thus we see in this case, that C \D has precisely

mn points, provided we take the multiplicity of .a W b W c/ to be the multiplicity of ba

as aroot of R�.

Hilbert polynomials (sketch) 135

Now suppose that R� has degree r < mn. Then R.X;Y / D Xmn�rP.X;Y / whereP.X;Y / is a homogeneous polynomial of degree r not divisible byX . ObviouslyR.0;1/D0, and so there is a point .0 W 1 W c/ in C \D, in contradiction with our assumption. 2

REMARK 6.35. The above proof has the defect that the notion of multiplicity has been tooobviously chosen to make the theorem come out right. It is possible to show that the theoremholds with the following more natural definition of multiplicity. Let P be an isolated pointof C \D. There will be an affine neighbourhood U of P and regular functions f and gon U such that C \U D V.f / and D\U D V.g/. We can regard f and g as elementsof the local ring OP , and clearly rad.f;g/D m, the maximal ideal in OP . It follows thatOP =.f;g/ is finite-dimensional over k, and we define the multiplicity of P in C \D tobe dimk.OP =.f;g//. For example, if C and D cross transversely at P , then f and g willform a system of local parameters at P — .f;g/Dm — and so the multiplicity is one.

The attempt to find good notions of multiplicities in very general situations motivatedmuch of the most interesting work in commutative algebra in the second half of the twenti-eth century.

Hilbert polynomials (sketch)

Recall that for a projective variety V � Pn,

khomŒV �D kŒX0; : : : ;Xn�=bD kŒx0; : : : ;xn�;

where b D I.V /. We observed that b is homogeneous, and therefore khomŒV � is a gradedring:

khomŒV �DM

m�0khomŒV �m;

where khomŒV �m is the subspace generated by the monomials in the xi of degreem. ClearlykhomŒV �m is a finite-dimensional k-vector space.

THEOREM 6.36. There is a unique polynomial P.V;T / such that P.V;m/D dimk kŒV �mfor all m sufficiently large.

PROOF. Omitted. 2

EXAMPLE 6.37. For V D Pn, khomŒV � D kŒX0; : : : ;Xn�, and (see the footnote on page126), dimkhomŒV �m D

�mCnn

�D

.mCn/���.mC1/nŠ

, and so

P.Pn;T /D�TCnn

�D.T Cn/ � � �.T C1/

nŠ:

The polynomial P.V;T / in the theorem is called the Hilbert polynomial of V . Despitethe notation, it depends not just on V but also on its embedding in projective space.

THEOREM 6.38. Let V be a projective variety of dimension d and degree ı; then

P.V;T /Dı

d ŠT d C terms of lower degree.

PROOF. Omitted. 2

136 6. PROJECTIVE VARIETIES

The degree of a projective variety is the number of points in the intersection of thevariety and of a general linear variety of complementary dimension (see later).

EXAMPLE 6.39. Let V be the image of the Veronese map

.a0 W a1/ 7! .ad0 W ad�10 a1 W : : : W a

d1 /WP

1! Pd :

Then khomŒV �m can be identified with the set of homogeneous polynomials of degree m �din two variables (look at the map A2 ! AdC1 given by the same equations), which is aspace of dimension dmC1, and so

P.V;T /D dT C1:

Thus V has dimension 1 (which we certainly knew) and degree d .

Macaulay knows how to compute Hilbert polynomials.References: Hartshorne 1977, I.7; Atiyah and Macdonald 1969, Chapter 11; Harris

1992, Lecture 13.

Exercises

6-1. Show that a point P on a projective curve F.X;Y;Z/ D 0 is singular if and only if@F=@X , @F=@Y , and @F=@Z are all zero at P . If P is nonsingular, show that the tangentline at P has the (homogeneous) equation

.@F=@X/PXC .@F=@Y /PY C .@F=@Z/PZ D 0.

Verify that Y 2ZDX3CaXZ2CbZ3 is nonsingular ifX3CaXCb has no repeated root,and find the tangent line at the point at infinity on the curve.

6-2. LetL be a line in P2 and let C be a nonsingular conic in P2 (i.e., a curve in P2 definedby a homogeneous polynomial of degree 2). Show that either

(a) L intersects C in exactly 2 points, or(b) L intersects C in exactly 1 point, and it is the tangent at that point.

6-3. Let V D V.Y �X2;Z�X3/� A3. Prove

(a) I.V /D .Y �X2;Z�X3/;(b) ZW �XY 2 I.V /� � kŒW;X;Y;Z�, but ZW �XY … ..Y �X2/�; .Z �X3/�/.

(Thus, if F1; : : : ;Fr generate a, it does not follow that F �1 ; : : : ;F�r generate a�, even

if a�is radical.)

6-4. Let P0; : : : ;Pr be points in Pn. Show that there is a hyperplane H in Pn passingthrough P0 but not passing through any of P1; : : : ;Pr .

6-5. Is the subsetf.a W b W c/ j a¤ 0; b ¤ 0g[f.1 W 0 W 0/g

of P2 locally closed?

6-6. Show that the image of the Segre map Pm�Pn! PmnCmCn (see 6.23) is not con-tained in any hyperplane of PmnCmCn.

CHAPTER 7Complete varieties

Throughout this chapter, k is an algebraically closed field.

Definition and basic properties

Complete varieties are the analogues in the category of algebraic varieties of compact topo-logical spaces in the category of Hausdorff topological spaces. Recall that the image of acompact space under a continuous map is compact, and hence is closed if the image spaceis Hausdorff. Moreover, a Hausdorff space V is compact if and only if, for all topologicalspacesW , the projection qWV �W !W is closed, i.e., maps closed sets to closed sets (seeBourbaki, N., General Topology, I, 10.2, Corollary 1 to Theorem 1).

DEFINITION 7.1. An algebraic variety V is said to be complete if for all algebraic varietiesW , the projection qWV �W !W is closed.

Note that a complete variety is required to be separated — we really mean it to be avariety and not a prevariety.

EXAMPLE 7.2. Consider the projection

.x;y/ 7! yWA1�A1! A1

This is not closed; for example, the variety V WXY D 1 is closed in A2 but its image in A1omits the origin. However, if we replace V with its closure in P1�A1, then its projectionis the whole of A1.

PROPOSITION 7.3. Let V be a complete variety.

(a) A closed subvariety of V is complete.(b) If V 0 is complete, so also is V �V 0.(c) For any morphism 'WV !W , '.V / is closed and complete; in particular, if V is a

subvariety of W , then it is closed in W .(d) If V is connected, then any regular map 'WV ! P1 is either constant or onto.(e) If V is connected, then any regular function on V is constant.

137

138 7. COMPLETE VARIETIES

PROOF. (a) Let Z be a closed subvariety of a complete variety V . Then for any varietyW , Z�W is closed in V �W , and so the restriction of the closed map qWV �W !W toZ�W is also closed.

(b) The projection V �V 0�W !W is the composite of the projections

V �V 0�W ! V 0�W !W;

both of which are closed.(c) Let �' D f.v;'.v//g � V �W be the graph of '. It is a closed subset of V �W

(because W is a variety, see 4.26), and '.V / is the projection of �' into W . Since V iscomplete, the projection is closed, and so '.V / is closed, and hence is a subvariety of W(see p76). Consider

�' �W ! '.V /�W !W:

The variety �' , being isomorphic to V (see 4.26), is complete, and so the mapping �' �W ! W is closed. As �' ! '.V / is surjective, it follows that '.V /�W ! W is alsoclosed.

(d) Recall that the only proper closed subsets of P1 are the finite sets, and such a set isconnected if and only if it consists of a single point. Because '.V / is connected and closed,it must either be a single point (and ' is constant) or P1 (and ' is onto).

(e) A regular function on V is a regular map f WV ! A1 � P1, which (d) shows to beconstant. 2

COROLLARY 7.4. A variety is complete if and only if its irreducible components are com-plete.

PROOF. It follows from (a) that the irreducible components of a complete variety are com-plete. Conversely, let V be a variety whose irreducible components Vi are complete. IfZ isclosed in V �W , then Zi

defDZ\ .Vi �W / is closed in Vi �W . Therefore, q.Zi / is closed

in W , and so q.Z/DSq.Zi / is also closed. 2

COROLLARY 7.5. A regular map 'WV !W from a complete connected variety to an affinevariety has image equal to a point. In particular, any complete connected affine variety is apoint.

PROOF. EmbedW as a closed subvariety of An, and write ' D .'1; : : : ;'n/ where 'i is thecomposite of ' with the coordinate function An! A1. Then each 'i is a regular functionon V , and hence is constant. (Alternatively, apply the remark following 4.11.) This provesthe first statement, and the second follows from the first applied to the identity map. 2

REMARK 7.6. (a) The statement that a complete variety V is closed in any larger varietyW perhaps explains the name: if V is complete, W is irreducible, and dimV D dimW ,then V DW — contrast An � Pn.

(b) Here is another criterion: a variety V is complete if and only if every regular mapC r fP g ! V extends to a regular map C ! V ; here P is a nonsingular point on a curveC . Intuitively, this says that Cauchy sequences have limits in V .

Projective varieties are complete 139

Projective varieties are complete

THEOREM 7.7. A projective variety is complete.

Before giving the proof, we shall need two lemmas.

LEMMA 7.8. A variety V is complete if qWV �W !W is a closed mapping for all irre-ducible affine varieties W (or even all affine spaces An).

PROOF. WriteW as a finite union of open subvarietiesW DSWi . IfZ is closed in V �W ,

then ZidefDZ\ .V �Wi / is closed in V �Wi . Therefore, q.Zi / is closed in Wi for all i . As

q.Zi /D q.Z/\Wi , this shows that q.Z/ is closed. 2

After (7.3a), it suffices to prove the Theorem for projective space Pn itself; thus wehave to prove that the projection Pn�W ! W is a closed mapping in the case that W isan irreducible affine variety. We shall need to understand the topology on W �Pn in termsof ideals. Let AD kŒW �, and let B D AŒX0; : : : ;Xn�. Note that B D A˝k kŒX0; : : : ;Xn�,and so we can view it as the ring of regular functions on W �AnC1: for f 2 A and g 2kŒX0; : : : ;Xn�, f ˝g is the function

.w;a/ 7! f .w/ �g.a/WW �AnC1! k:

The ring B has an obvious grading — a monomial aX i00 : : :Xinn , a 2A, has degree

Pij —

and so we have the notion of a homogeneous ideal b � B . It makes sense to speak of thezero set V.b/ � W �Pn of such an ideal. For any ideal a � A, aB is homogeneous, andV.aB/D V.a/�Pn.

LEMMA 7.9. (a) For each homogeneous ideal b � B , the set V.b/ is closed, and everyclosed subset of W �Pn is of this form.

(b) The set V.b/ is empty if and only if rad.b/� .X0; : : : ;Xn/.(c) If W is irreducible, then W D V.b/ for some homogeneous prime ideal b.

PROOF. In the case that A D k, we proved this in (6.1) and (6.2), and similar argumentsapply in the present more general situation. For example, to see that V.b/ is closed, coverPn with the standard open affines Ui and show that V.b/\Ui is closed for all i .

The set V.b/ is empty if and only if the cone V aff.b/ � W �AnC1 defined by b iscontained in W �foriging. ButX

ai0:::inXi00 : : :X

inn ; ai0:::in 2 kŒW �;

is zero on W �foriging if and only if its constant term is zero, and so

I aff.W �foriging/D .X0;X1; : : : ;Xn/:

Thus, the Nullstellensatz shows that V.b/ D ; ) rad.b/ D .X0; : : : ;Xn/. Conversely, ifXNi 2 b for all i , then obviously V.b/ is empty.

For (c), note that if V.b/ is irreducible, then the closure of its inverse image in W �AnC1 is also irreducible, and so IV.b/ is prime. 2

140 7. COMPLETE VARIETIES

PROOF (OF 7.7). Write p for the projectionW �Pn!W . We have to show thatZ closedin W �Pn implies p.Z/ closed in W . If Z is empty, this is true, and so we can assume itto be nonempty. Then Z is a finite union of irreducible closed subsets Zi of W �Pn, and itsuffices to show that each p.Zi / is closed. Thus we may assume that Z is irreducible, andhence that Z D V.b/ with b a homogeneous prime ideal in B D AŒX0; : : : ;Xn�.

If p.Z/ is contained in some closed subvariety W 0 of W , then Z is contained in W 0�Pn, and we can replaceW withW 0. This allows us to assume that p.Z/ is dense inW , andwe now have to show that p.Z/DW .

Because p.Z/ is dense in W , the image of the cone V aff.b/ under the projection W �AnC1!W is also dense in W , and so (see 3.22a) the map A! B=b is injective.

Let w 2W : we shall show that if w … p.Z/, i.e., if there does not exist a P 2 Pn suchthat .w;P / 2Z, then p.Z/ is empty, which is a contradiction.

Let m� A be the maximal ideal corresponding to w. Then mBCb is a homogeneousideal, and V.mBCb/D V.mB/\V.b/D .w�Pn/\V.b/, and so w will be in the imageof Z unless V.mBC b/ ¤ ;. But if V.mBC b/ D ;, then mBC b � .X0; : : : ;Xn/

N forsome N (by 7.9b), and so mBC b contains the set BN of homogeneous polynomials ofdegree N . Because mB and b are homogeneous ideals,

BN �mBCb H) BN DmBN CBN \b:

In detail: the first inclusion says that an f 2BN can be written f D gChwith g 2mB andh 2 b. On equating homogeneous components, we find that fN D gN ChN . Moreover:fN D f ; if g D

Pmibi , mi 2 m, bi 2 B , then gN D

PmibiN ; and hN 2 b because b is

homogeneous. Together these show f 2mBN CBN \b.LetM DBN =BN \b, regarded as anA-module. The displayed equation says thatM D

mM . The argument in the proof of Nakayama’s lemma (1.3) shows that .1Cm/M D 0 forsome m 2 m. Because A! B=b is injective, the image of 1Cm in B=b is nonzero. ButM D BN =BN \b � B=b, which is an integral domain, and so the equation .1Cm/M D0 implies that M D 0. Hence BN � b, and so XNi 2 b for all i , which contradicts theassumption that Z D V.b/ is nonempty. 2

REMARK 7.10. In Example 6.19 above, we showed that every finite set of points in aprojective variety is contained in an open affine subvariety. There is a partial converse tothis statement: let V be a nonsingular complete irreducible variety; if every finite set ofpoints in V is contained in an open affine subset of V then V is projective. (Conjecture ofChevalley; proved by Kleiman.1)

Elimination theory

We have shown that, for any closed subset Z of Pm�W , the projection q.Z/ of Z in W isclosed. Elimination theory2 is concerned with providing an algorithm for passing from theequations defining Z to the equations defining q.Z/. We illustrate this in one case.

1Kleiman, Steven L., Toward a numerical theory of ampleness. Ann. of Math. (2) 84 1966 293–344.See also,

Hartshorne, Robin, Ample subvarieties of algebraic varieties. Lecture Notes in Mathematics, Vol. 156 Springer,1970, I �9 p45.

2Elimination theory became unfashionable several decades ago—one prominent algebraic geometer wentso far as to announce that Theorem 7.7 eliminated elimination theory from mathematics, provoking Abhyankar,who prefers equations to abstractions, to start the chant “eliminate the eliminators of elimination theory”. Withthe rise of computers, it has become fashionable again.

Elimination theory 141

Let P D s0XmC s1Xm�1C�� �C sm andQD t0XnC t1Xn�1C�� �C tn be polynomi-als. The resultant of P and Q is defined to be the determinantˇ

ˇˇs0 s1 : : : sm

s0 : : : sm: : : : : :

t0 t1 : : : tnt0 : : : tn

: : : : : :

ˇˇˇ

n rows

m rows

There are n rows of s’s andm rows of t ’s, so that the matrix is .mCn/� .mCn/; all blankspaces are to be filled with zeros. The resultant is a polynomial in the coefficients of P andQ.

PROPOSITION 7.11. The resultant Res.P;Q/D 0 if and only if

(a) both s0 and t0 are zero; or(b) the two polynomials have a common root.

PROOF. If (a) holds, then Res.P;Q/D 0 because the first column is zero. Suppose that ˛is a common root of P and Q, so that there exist polynomials P1 and Q1 of degrees m�1and n�1 respectively such that

P.X/D .X �˛/P1.X/; Q.X/D .X �˛/Q1.X/:

Using these equalities, we find that

P.X/Q1.X/�Q.X/P1.X/D 0: (21)

On equating the coefficients of XmCn�1; : : : ;X;1 in (21) to zero, we find that the coef-ficients of P1 and Q1 are the solutions of a system of mC n linear equations in mC nunknowns. The matrix of coefficients of the system is the transpose of the matrix0BBBBBB@

s0 s1 : : : sms0 : : : sm

: : : : : :

t0 t1 : : : tnt0 : : : tn

: : : : : :

1CCCCCCAThe existence of the solution shows that this matrix has determinant zero, which impliesthat Res.P;Q/D 0.

Conversely, suppose that Res.P;Q/D 0 but neither s0 nor t0 is zero. Because the abovematrix has determinant zero, we can solve the linear equations to find polynomials P1 andQ1 satisfying (21). A root ˛ of P must be also be a root of P1 or of Q. If the former,cancel X � ˛ from the left hand side of (21), and consider a root ˇ of P1=.X � ˛/. AsdegP1 < degP , this argument eventually leads to a root of P that is not a root of P1, andso must be a root of Q. 2

142 7. COMPLETE VARIETIES

The proposition can be restated in projective terms. We define the resultant of twohomogeneous polynomials

P.X;Y /D s0XmC s1X

m�1Y C�� �C smYm; Q.X;Y /D t0X

nC�� �C tnY

n;

exactly as in the nonhomogeneous case.

PROPOSITION 7.12. The resultant Res.P;Q/D 0 if and only if P and Q have a commonzero in P1.

PROOF. The zeros of P.X;Y / in P1 are of the form:

(a) .1 W 0/ in the case that s0 D 0;(b) .a W 1/ with a a root of P.X;1/.

Since a similar statement is true for Q.X;Y /, (7.12) is a restatement of (7.11). 2

Now regard the coefficients of P and Q as indeterminates. The pairs of polynomials.P;Q/ are parametrized by the spaceAmC1�AnC1DAmCnC2. Consider the closed subsetV.P;Q/ in AmCnC2�P1. The proposition shows that its projection on AmCnC2 is the setdefined by Res.P;Q/D 0. Thus, not only have we shown that the projection of V.P;Q/is closed, but we have given an algorithm for passing from the polynomials defining theclosed set to those defining its projection.

Elimination theory does this in general. Given a family of polynomials

Pi .T1; : : : ;TmIX0; : : : ;Xn/;

homogeneous in the Xi , elimination theory gives an algorithm for finding polynomialsRj .T1; : : : ;Tn/ such that the Pi .a1; : : : ;amIX0; : : : ;Xn/ have a common zero if and only ifRj .a1; : : : ;an/D 0 for all j . (Theorem 7.7 shows only that the Rj exist.) See Cox et al.1992, Chapter 8, Section 5..

Maple can find the resultant of two polynomials in one variable: for example, entering“resultant..xCa/5; .xC b/5;x/” gives the answer .�aC b/25. Explanation: the polyno-mials have a common root if and only if aD b, and this can happen in 25 ways. Macaulaydoesn’t seem to know how to do more.

The rigidity theorem

The paucity of maps between complete varieties has some interesting consequences. Firstan observation: for any point w 2W , the projection map V �W ! V defines an isomor-phism V �fwg ! V with inverse v 7! .v;w/WV ! V �W (this map is regular because itscomponents are).

THEOREM 7.13 (RIGIDITY THEOREM). Let 'WV �W !Z be a regular map, and assumethat V is complete, that V and W are irreducible, and that Z is separated. If there existpoints v0 2 V , w0 2W , z0 2Z such that

'.V �fw0g/D fz0g D '.fv0g�W /,

then '.V �W /D fz0g.

Theorems of Chow 143

PROOF. Because V is complete, the projection map qWV �W !W is closed. Therefore,for any open affine neighbourhood U of z0,

T D q.'�1.ZrU//

is closed in W . Note that

W rT D fw 2W j '.V;w/� U g,

and so w0 2W rT . In particular,W rT is nonempty, and so it is dense inW . As V �fwgis complete and U is affine, '.V �fwg/ must be a point whenever w 2W rT : in fact,

'.V;w/D '.v0;w/D fz0g:

We have shown that ' takes the constant value z0 on the dense subset V � .W � T / ofV �W , and therefore on the whole of V �W . 2

In more colloquial terms, the theorem says that if ' collapses a vertical and a horizontalslice to a point, then it collapses the whole of V �W to a point, which must therefore be“rigid”.

An abelian variety is a complete connected group variety.

COROLLARY 7.14. Every regular map ˛WA! B of abelian varieties is the composite of ahomomorphism with a translation; in particular, a regular map ˛WA!B such that ˛.0/D 0is a homomorphism.

PROOF. After composing ˛ with a translation, we may suppose that ˛.0/ D 0. Considerthe map

'WA�A! B; '.a;a0/D ˛.aCa0/�˛.a/�˛.a0/:

Then '.A�0/D 0D '.0�A/ and so ' D 0. This means that ˛ is a homomorphism. 2

COROLLARY 7.15. The group law on an abelian variety is commutative.

PROOF. Commutative groups are distinguished among all groups by the fact that the maptaking an element to its inverse is a homomorphism: if .gh/�1 D g�1h�1, then, on takinginverses, we find that ghD hg. Since the negative map, a 7! �aWA!A, takes the identityelement to itself, the preceding corollary shows that it is a homomorphism. 2

Theorems of Chow

THEOREM 7.16. For every algebraic variety V , there exists a projective algebraic varietyW and a regular map ' from an open dense subset U of W to V whose graph is closed inV �W ; the set U DW if and only if V is complete.

PROOF. To be added. 2

See:

144 7. COMPLETE VARIETIES

Chow, W-L., On the projective embedding of homogeneous varieties, Lef-schetz’s volume, Princeton 1956.

Serre, Jean-Pierre. Geometrie algebrique et geometrie analytique. Ann.Inst. Fourier, Grenoble 6 (1955–1956), 1–42 (p12).

THEOREM 7.17. For any complete algebraic variety V , there exists a projective algebraicvariety W and a surjective birational map W ! V .

PROOF. To be added. (See Mumford 1999, p60.) 2

Theorem 7.17 is usually known as Chow’s Lemma.

Nagata’s Embedding Theorem

A necessary condition for a prevariety to be an open subvariety of a complete variety is thatit be separated. A theorem of Nagata says that this condition is also sufficient.

THEOREM 7.18. For every variety V , there exists an open immersion V ! W with Wcomplete.

The theorem is important, but the proof is quite difficult, even for varieties. It wasoriginally proved by Nagata:

Nagata, Masayoshi. Imbedding of an abstract variety in a complete variety. J.Math. Kyoto Univ. 2 1962 1–10; A generalization of the imbedding problem ofan abstract variety in a complete variety. J. Math. Kyoto Univ. 3 1963 89–102.

For more modern expositions, see:

Lutkebohmert, W. On compactification of schemes. Manuscripta Math. 80(1993), no. 1, 95–111.Deligne, P., Le theoreme de plongement de Nagata, personal notes (publishedas Kyoto J. Math. 50, Number 4 (2010), 661-670.Conrad, B., Deligne’s notes on Nagata compactifications. J. Ramanujan Math.Soc. 22 (2007), no. 3, 205–257.Vojta, P., Nagata’s embedding theorem, arXiv:0706.1907.

Exercises

7-1. Identify the set of homogeneous polynomials F.X;Y /DPaijX

iY j , 0 � i;j �m,with an affine space. Show that the subset of reducible polynomials is closed.

7-2. Let V and W be complete irreducible varieties, and let A be an abelian variety. LetP and Q be points of V and W . Show that any regular map hWV �W ! A such thath.P;Q/D 0 can be written hD f ıpCg ıq where f WV ! A and gWW ! A are regularmaps carrying P and Q to 0 and p and q are the projections V �W ! V;W .

CHAPTER 8Finite Maps

Throughout this chapter, k is an algebraically closed field.

Definition and basic properties

Recall that an A-algebra B is said to be finite if it is finitely generated as an A-module. Thisis equivalent to B being finitely generated as an A-algebra and integral over A. Recall alsothat a variety V is affine if and only if � .V;OV / is an affine k-algebra and the canonicalmap .V;OV /! Spm.� .V;OV // is an isomorphism (3.13).

DEFINITION 8.1. A regular map 'WW ! V is said to be finite if for all open affine subsetsU of V , '�1.U / is an affine variety and kŒ'�1.U /� is a finite kŒU �-algebra.

For example, suppose W and V are affine and kŒW � is a finite kŒV �-algebra. Then ' isfinite because, for any open affine U in V , '�1.U / is affine with

kŒ'�1.U /�' kŒW �˝kŒV � kŒU � (22)

(see 4.29, 4.30); in particular, the canonical map

'�1.U /! Spm.� .'�1.U /;OW / (23)

is an isomorphism.

PROPOSITION 8.2. It suffices to check the condition in the definition for all subsets in oneopen affine covering of V .

Unfortunately, this is not as obvious as it looks. We first need a lemma.

LEMMA 8.3. Let 'WW ! V be a regular map with V affine, and let U be an open affinein V . There is a canonical isomorphism of k-algebras

� .W;OW /˝kŒV � kŒU �! � .'�1.U /;OW /:

PROOF. Let U 0 D '�1.U /. The map is defined by the kŒV �-bilinear pairing

.f;g/ 7! .f jU 0 ;g ı'jU 0/W� .W;OW /�kŒU �! � .U 0;OW /:

145

146 8. FINITE MAPS

When W is also affine, it is the isomorphism (22).Let W D

SWi be a finite open affine covering of W , and consider the commutative

diagram:

0 ! � .W;OW /˝kŒV � kŒU � !Qi

� .Wi ;OW /˝kŒV � kŒU � ⇒Qi;j

� .Wij ;OW /˝kŒV � kŒU �

# # #

0 ! � .U 0;OW / !Qi

� .U 0\Wi ;OW / ⇒Qi;j

� .U \Wij ;OW /

HereWij DWi\Wj . The bottom row is exact because OW is a sheaf, and the top row is ex-act because OW is a sheaf and kŒU � is flat over kŒV � (see Section 1)1. The varietiesWi andWi \Wj are all affine, and so the two vertical arrows at right are products of isomorphisms(22). This implies that the first is also an isomorphism. 2

PROOF (OF THE PROPOSITION). Let Vi be an open affine covering of V (which we maysuppose to be finite) such that Wi Ddef '

�1.Vi / is an affine subvariety of W for all i andkŒWi � is a finite kŒVi �-algebra. Let U be an open affine in V , and let U 0 D '�1.U /. Then� .U 0;OW / is a subalgebra of

Qi � .U

0\Wi ;OW /, and so it is an affine k-algebra finiteover kŒU �.2 We have a morphism of varieties over V

U 0 Spm.� .U 0;OW //

V

canonical

(24)

which we shall show to be an isomorphism. We know (see (23)) that each of the maps

U 0\Wi ! Spm.� .U 0\Wi ;OW //

is an isomorphism. But (8.2) shows that Spm.� .U 0\Wi ;OW // is the inverse image of Viin Spm.� .U 0;OW //. Therefore the canonical morphism is an isomorphism over each Vi ,and so it is an isomorphism. 2

PROPOSITION 8.4. (a) For any closed subvarietyZ of V , the inclusionZ ,! V is finite.(b) The composite of two finite morphisms is finite.(c) The product of two finite morphisms is finite.

PROOF. (a) Let U be an open affine subvariety of V . Then Z\U is a closed subvariety ofU . It is therefore affine, and the map Z\U ! U corresponds to a map A!A=a of rings,which is obviously finite.

1A sequence 0!M 0!M !M 00 is exact if and only if 0! Am˝AM0! Am˝AM ! Am˝AM

00

is exact for all maximal ideals m of A. This implies the claim because kŒU �mP 'OU;P 'OV;P ' kŒV �mPfor all P 2 U .

2Recall that a module over a noetherian ring is noetherian if and only if it is finitely generated, and thata submodule of a noetherian module is noetherian. Therefore, a submodule of a finitely generated module isfinitely generated.

Definition and basic properties 147

(b) If B is a finite A-algebra and C is a finite B-algebra, then C is a finite A-algebra.To see this, note that if fbig is a set of generators for B as an A-module, and fcj g is a set ofgenerators for C as a B-module, then fbicj g is a set of generators for C as an A-module.

(c) If B and B 0 are respectively finite A and A0-algebras, then B˝k B 0 is a finite A˝kA0-algebra. To see this, note that if fbig is a set of generators for B as an A-module, andfb0j g is a set of generators for B 0 as an A-module, the fbi ˝ b0j g is a set of generators forB˝AB

0 as an A-module. 2

By way of contrast, an open immersion is rarely finite. For example, the inclusionA1�f0g ,! A1 is not finite because the ring kŒT;T �1� is not finitely generated as a kŒT �-module (any finitely generated kŒT �-submodule of kŒT;T �1� is contained in T �nkŒT � forsome n).

The fibres of a regular map 'WW ! V are the subvarieties '�1.P / of W for P 2 V .When the fibres are all finite, ' is said to be quasi-finite.

PROPOSITION 8.5. A finite map 'WW ! V is quasi-finite.

PROOF. Let P 2 V ; we wish to show '�1.P / is finite. After replacing V with an affineneighbourhood of P , we can suppose that it is affine, and then W will be affine also. Themap ' then corresponds to a map ˛WA!B of affine k-algebras, and a point Q of W mapsto P if and only ˛�1.mQ/ D mP . But this holds if and only if mQ � ˛.mP /, and sothe points of W mapping to P are in one-to-one correspondence with the maximal idealsof B=˛.m/B . Clearly B=˛.m/B is generated as a k-vector space by the image of anygenerating set for B as an A-module, and the next lemma shows that it has only finitelymany maximal ideals. 2

LEMMA 8.6. A finite k-algebra A has only finitely many maximal ideals.

PROOF. Let m1; : : : ;mn be maximal ideals in A. They are obviously coprime in pairs, andso the Chinese Remainder Theorem (1.1) shows that the map

A! A=m1� � � ��A=mn; a 7! .: : : ;ai modmi ; : : :/;

is surjective. It follows that dimkA�P

dimk.A=mi /�n (dimensions as k-vector spaces).2

THEOREM 8.7. A finite map 'WW ! V is closed.

PROOF. Again we can assume V and W to be affine. Let Z be a closed subset of W . Therestriction of ' to Z is finite (by 8.4a and b), and so we can replace W with Z; we thenhave to show that Im.'/ is closed. The map corresponds to a finite map of rings A! B .This will factors as A! A=a ,! B , from which we obtain maps

Spm.B/! Spm.A=a/ ,! Spm.A/:

The second map identifies Spm.A=a/ with the closed subvariety V.a/ of Spm.A/, and so itremains to show that the first map is surjective. This is a consequence of the next lemma.2

LEMMA 8.8 (GOING-UP THEOREM). Let A� B be rings with B integral over A.

148 8. FINITE MAPS

(a) For every prime ideal p of A, there is a prime ideal q of B such that q\AD p.(b) Let pD q\A; then p is maximal if and only if q is maximal.

PROOF. (a) If S is a multiplicative subset of a ring A, then the prime ideals of S�1Aare in one-to-one correspondence with the prime ideals of A not meeting S (see 1.30). Ittherefore suffices to prove (a) afterA and B have been replaced by S�1A and S�1B , whereS D A�p. Thus we may assume that A is local, and that p is its unique maximal ideal. Inthis case, for all proper ideals b of B , b\A � p (otherwise b � A 3 1/. To complete theproof of (a), I shall show that for all maximal ideals n of B , n\AD p.

Consider B=n � A=.n\A/. Here B=n is a field, which is integral over its subringA=.n\A/, and n\A will be equal to p if and only if A=.n\A/ is a field. This followsfrom Lemma 8.9 below.

(b) The ring B=q contains A=p, and it is integral over A=p. If q is maximal, thenLemma 8.9 shows that p is also. For the converse, note that any integral domain integralover a field is a field because it is a union of integral domains finite over the field, whichare automatically fields (left multiplication by an element is injective, and hence surjective,being a linear map of a finite-dimensional vector space). 2

LEMMA 8.9. Let A be a subring of a fieldK. IfK is integral over A, then A is also a field.

PROOF. Let a be a nonzero element of A. Then a�1 2K, and it is integral over A:

.a�1/nCa1.a�1/n�1C�� �Can D 0; ai 2 A:

On multiplying through by an�1, we find that

a�1Ca1C�� �Canan�1D 0;

from which it follows that a�1 2 A. 2

COROLLARY 8.10. Let 'WW ! V be finite; if V is complete, then so also is W .

PROOF. Consider

W �T ! V �T ! T; .w; t/ 7! .'.w/; t/ 7! t:

Because W � T ! V � T is finite (see 8.4c), it is closed, and because V is complete,V �T ! T is closed. A composite of closed maps is closed, and therefore the projectionW �T ! T is closed. 2

EXAMPLE 8.11. (a) Project XY D 1 onto the X axis. This map is quasi-finite but notfinite, because kŒX;X�1� is not finite over kŒX�.

(b) The mapA2rforiging ,!A2 is quasi-finite but not finite, because the inverse imageof A2 is not affine (3.21).

(c) LetV D V.XnCT1X

n�1C�� �CTn/� AnC1;

and consider the projection map

.a1; : : : ;an;x/ 7! .a1; : : : ;an/WV ! An:

Noether Normalization Theorem 149

The fibre over any point .a1; : : : ;an/ 2 An is the set of solutions of

XnCa1Xn�1C�� �Can D 0;

and so it has exactly n points, counted with multiplicities. The map is certainly quasi-finite;it is also finite because it corresponds to the finite map of k-algebras,

kŒT1; : : : ;Tn�! kŒT1; : : : ;Tn;X�=.XnCT1X

n�1C�� �CTn/:

(d) LetV D V.T0X

nCT1X

n�1C�� �CTn/� AnC2:

The projection.a0; : : : ;an;x/ 7! .a1; : : : ;an/WV

'�! AnC1

has finite fibres except for the fibre above o D .0; : : : ;0/, which is A1. The restriction'jV r '�1.o/ is quasi-finite, but not finite. Above points of the form .0; : : : ;0;�; : : : ;�/

some of the roots “vanish off to1”. (Example (a) is a special case of this.)

(e) LetP.X;Y /D T0X

nCT1X

n�1Y C :::CTnYn;

and let V be its zero set in P1 � .AnC1 r fog/. In this case, the projection map V !AnC1r fog is finite. (Prove this directly, or apply 8.23 below.)

(f) The morphism A1!A2, t 7! .t2; t3/ is finite because the image of kŒX;Y � in kŒT �is kŒT 2;T 3�, and f1;T g is a set of generators for kŒT � over this subring.

(g) The morphism A1! A1, a 7! am is finite (special case of (c)).

(h) The obvious map

.A1 with the origin doubled /! A1

is quasi-finite but not finite (the inverse image of A1 is not affine).

The Frobenius map t 7! tpWA1!A1 in characteristic p¤ 0 and the map t 7! .t2; t3/WA1!V.Y 2�X3/� A2 from the line to the cuspidal cubic (see 3.18c) are examples of finite bi-jective regular maps that are not isomorphisms.

Noether Normalization Theorem

This theorem sometimes allows us to reduce the proofs of statements about affine varietiesto the case of An.

THEOREM 8.12. For any irreducible affine algebraic variety V of a variety of dimensiond , there is a finite surjective map 'WV ! Ad .

PROOF. This is a geometric re-statement of the following theorem. 2

THEOREM 8.13 (NOETHER NORMALIZATION THEOREM). Let A be a finitely generatedk-algebra, and assume that A is an integral domain. Then there exist elements y1; : : : ;yd 2A that are algebraically independent over k and such that A is integral over kŒy1; : : : ;yd �.

150 8. FINITE MAPS

Let x1; : : : ;xn generate A as a k-algebra. We can renumber the xi so that x1; : : : ;xd arealgebraically independent and xdC1; : : : ;xn are algebraically dependent on x1; : : : ;xd (FT,8.12).

Because xn is algebraically dependent on x1; : : : ;xd , there exists a nonzero polynomialf .X1; : : : ;Xd ;T / such that f .x1; : : : ;xd ;xn/D 0. Write

f .X1; : : : ;Xd ;T /D a0TmCa1T

m�1C�� �Cam

with ai 2 kŒX1; : : : ;Xd � .� kŒx1; : : : ;xd �/: If a0 is a nonzero constant, we can dividethrough by it, and then xn will satisfy a monic polynomial with coefficients in kŒx1; : : : ;xd �,that is, xn will be integral (not merely algebraic) over kŒx1; : : : ;xd �. The next lemma sug-gest how we might achieve this happy state by making a linear change of variables.

LEMMA 8.14. If F.X1; : : : ;Xd ;T / is a homogeneous polynomial of degree r , then

F.X1C�1T; : : : ;Xd C�dT;T /D F.�1; : : : ;�d ;1/TrC terms of degree< r in T:

PROOF. The polynomial F.X1C�1T; : : : ;Xd C�dT;T / is still homogeneous of degree r(in X1; : : : ;Xd ;T ), and the coefficient of the monomial T r in it can be obtained by substi-tuting 0 for each Xi and 1 for T . 2

PROOF (OF THEOREM 8.13). Note that unless F.X1; : : : ;Xd ;T / is the zero polynomial,it will always be possible to choose .�1; : : : ;�d / so that F.�1; : : : ;�d ;1/¤ 0 — substitut-ing T D 1 merely dehomogenizes the polynomial (no cancellation of terms occurs), and anonzero polynomial can’t be zero on all of kn (Exercise 1-1).

Let F be the homogeneous part of highest degree of f , and choose .�1; : : : ;�d / so thatF.�1; : : : ;�d ;1/¤ 0: The lemma then shows that

f .X1C�1T; : : : ;Xd C�dT;T /D cTrCb1T

r�1C�� �Cb0;

with c D F.�1; : : : ;�d ;1/ 2 k�, bi 2 kŒX1; : : : ;Xd �, degbi < r . On substituting xn for Tand xi ��ixn for Xi we obtain an equation demonstrating that xn is integral over kŒx1��1xn; : : : ;xd ��dxn�. Put x0i D xi ��ixn, 1 � i � d . Then xn is integral over the ringkŒx01; : : : ;x

0d�, and it follows that A is integral over A0 D kŒx01; : : : ;x

0d;xdC1; : : : ;xn�1�.

Repeat the process for A0, and continue until the theorem is proved. 2

REMARK 8.15. The above proof uses only that k is infinite, not that it is algebraicallyclosed (that’s all one needs for a nonzero polynomial not to be zero on all of kn). There areother proofs that work also for finite fields (see CA 5.11), but the above proof is simpler andgives us the additional information that the yi ’s can be chosen to be linear combinations ofthe xi . This has the following geometric interpretation:

let V be a closed subvariety of An of dimension d ; then there exists a linearmap An! Ad whose restriction to V is a finite map V � Ad .

Zariski’s main theorem

An obvious way to construct a nonfinite quasi-finite map W ! V is to take a finite mapW 0! V and remove a closed subset of W 0. Zariski’s Main Theorem shows that, when Wand V are separated, every quasi-finite map arises in this way.

Zariski’s main theorem 151

THEOREM 8.16 (ZARISKI’S MAIN THEOREM). Any quasi-finite map of varieties 'WW !

V factors into W�,!W 0

'0

! V with '0 finite and � an open immersion.

PROOF. Omitted — see the references below (152). 2

REMARK 8.17. Assume (for simplicity) that V and W are irreducible and affine. Theproof of the theorem provides the following description of the factorization: it correspondsto the maps

kŒV �! kŒW 0�! kŒW �

with kŒW 0� the integral closure of kŒV � in kŒW �.

A regular map 'WW ! V of irreducible varieties is said to be birational if it inducesan isomorphism k.V /! k.W / on the fields of rational functions (that is, if it demonstratesthat W and V are birationally equivalent).

REMARK 8.18. One may ask how a birational regular map 'WW ! V can fail to be anisomorphism. Here are three examples.

(a) The inclusion of an open subset into a variety is birational.(b) The map A1! C , t 7! .t2; t3/, is birational. Here C is the cubic Y 2 DX3, and the

map kŒC �! kŒA1�D kŒT � identifies kŒC � with the subring kŒT 2;T 3� of kŒT �. Bothrings have k.T / as their fields of fractions.

(c) For any smooth variety V and point P 2 V , there is a regular birational map 'WV 0!V such that the restriction of ' to V 0�'�1.P / is an isomorphism onto V �P , but'�1.P / is the projective space attached to the vector space TP .V /.

The next result says that, if we require the target variety to be normal (thereby excludingexample (b)), and we require the map to be quasi-finite (thereby excluding example (c)),then we are left with (a).

COROLLARY 8.19. Let 'WW ! V be a birational regular map of irreducible varieties.Assume

(a) V is normal, and(b) ' is quasi-finite.

Then ' is an isomorphism of W onto an open subset of V .

PROOF. Factor ' as in the theorem. For each open affine subset U of V , kŒ'0�1.U /� is theintegral closure of kŒU � in k.W /. But k.W / D k.V / (because ' is birational), and kŒU �is integrally closed in k.V / (because V is normal), and so U D '0�1.U / (as varieties). Itfollows that W 0 D V . 2

COROLLARY 8.20. Any quasi-finite regular map 'WW ! V with W complete is finite.

PROOF. In this case, �WW ,!W 0 must be an isomorphism (7.3). 2

152 8. FINITE MAPS

REMARK 8.21. Let W and V be irreducible varieties, and let 'WW ! V be a dominantmap. It induces a map k.V / ,! k.W /, and if dimW D dimV , then k.W / is a finite exten-sion of k.V /. We shall see later that, if n is the separable degree of k.V / over k.W /, thenthere is an open subset U of W such that ' is n W 1 on U , i.e., for P 2 '.U /, '�1.P / hasexactly n points.

Now suppose that ' is a bijective regular map W ! V . We shall see later that thisimplies that W and V have the same dimension. Assume:

(a) k.W / is separable over k.V /;(b) V is normal.

From (a) and the preceding discussion, we find that ' is birational, and from (b) andthe corollary, we find that ' is an isomorphism of W onto an open subset of V ; as it issurjective, it must be an isomorphism of W onto V . We conclude: a bijective regular map'WW ! V satisfying the conditions (a) and (b) is an isomorphism.

NOTES. The full name of Theorem 8.16 is “the main theorem of Zariski’s paper Transactions AMS,53 (1943), 490-532”. Zariski’s original statement is that in (8.19). Grothendieck proved it in thestronger form (8.16) for all schemes. There is a good discussion of the theorem in Mumford 1999,III.9. For a proof see Musili, C., Algebraic geometry for beginners. Texts and Readings in Mathe-matics, 20. Hindustan Book Agency, New Delhi, 2001, �65.

The base change of a finite map

Recall that the base change of a regular map 'WV ! S is the map '0 in the diagram:

V �S W 0

����! V??y'0 ??y'W

����! S:

PROPOSITION 8.22. The base change of a finite map is finite.

PROOF. We may assume that all the varieties concerned are affine. Then the statement be-comes: if A is a finite R-algebra, then A˝RB=N is a finite B-algebra, which is obvious.2

Proper maps

A regular map � WV ! S of varieties is said to be proper if it is “universally closed”, that is,if for all maps T ! S , the base change � 0WV �S T ! T of � is closed. Note that a varietyV is complete if and only if the map V ! fpointg is proper. From its very definition, it isclear that the base change of a proper map is proper. In particular, if � WV ! S is proper,then ��1.P / is a complete variety for all P 2 S .

PROPOSITION 8.23. A finite map of varieties is proper.

PROOF. The base change of a finite map is finite, and hence closed. 2

PROPOSITION 8.24. If V ! S is proper and S is complete, then V is complete.

Proper maps 153

PROOF. Let T be a variety, and consider

V ���� V �T??y ??yclosed

S ���� S �T??y ??yclosed

fpointg ���� T

As V �T ' V �S .S �T / and V ! S is proper, the map V �T ! S �T is closed, and asS is complete, the map S �T ! T is closed. Therefore, V �T ! T is closed. 2

COROLLARY 8.25. The inverse image of a complete variety under a proper map is com-plete.

PROOF. Let � WV ! S be proper, and letZ be a complete subvariety of S . Then V �SZ!Z is proper, and V �S Z ' ��1.Z/. 2

PROPOSITION 8.26. Let � WV ! S be a proper map. The image �W of any completesubvariety W of V is a complete subvariety of S .

PROOF. The image �W is certainly closed in S . Let T be a variety, and consider thediagram

W ���� W �T??yonto

??yonto

�W ���� �W �T??yT:

Any closed subvariety Z of �W � T is the image of a closed subvariety Z0 of W � T(namely, of its inverse image), and the image of Z0 in T is closed becauseW is complete.2

The next result (whose proof requires Zariski’s Main Theorem) gives a purely geometriccriterion for a regular map to be finite.

PROPOSITION 8.27. A proper quasi-finite map 'WW ! V of varieties is finite.

PROOF. Factor ' into W�,!W 0

˛!W with ˛ finite and � an open immersion. Factor � into

Ww 7!.w;�w/�������! W �V W

0.w;w 0/ 7!w 0

��������! W 0:

The image of the first map is ��, which is closed because W 0 is a variety (see 4.26; W 0 isseparated because it is finite over a variety — exercise). Because ' is proper, the secondmap is closed. Hence � is an open immersion with closed image. It follows that its image isa connected component of W 0, and that W is isomorphic to that connected component. 2

154 8. FINITE MAPS

If W and V are curves, then any surjective map W ! V is closed. Thus it is easy togive examples of closed surjective quasi-finite nonfinite maps. For example, the map

a 7! anWA1r f0g ! A1;

which corresponds to the map on rings

kŒT �! kŒT;T �1�; T 7! T n;

is such a map. This doesn’t violate the theorem, because the map is only closed, not uni-versally closed.

Exercises

8-1. Prove that a finite map is an isomorphism if and only if it is bijective and etale. (Cf.Harris 1992, 14.9.)

8-2. Give an example of a surjective quasi-finite regular map that is not finite (differentfrom any in the notes).

8-3. Let 'WV ! W be a regular map with the property that '�1.U / is an open affinesubset ofW whenever U is an open affine subset of V . Show that if V is separated, then soalso is W .

8-4. For every n � 1, find a finite map 'WW ! V with the following property: for all1� i � n,

VidefD fP 2 V j '�1.P / has � i pointsg

is a closed subvariety of dimension i .

CHAPTER 9Dimension Theory

Throughout this chapter, k is an algebraically closed field. Recall that to an irreduciblevariety V , we attach a field k.V / — it is the field of fractions of kŒU � for any open affinesubvariety U of V , and also the field of fractions of OP for any point P in V . We definedthe dimension of V to be the transcendence degree of k.V / over k. Note that, directly fromthis definition, dimV D dimU for any open subvariety U of V . Also, that if W ! V isa finite surjective map, then dimW D dimV (because k.W / is a finite field extension ofk.V //.

When V is not irreducible, we defined the dimension of V to be the maximum dimen-sion of an irreducible component of V , and we said that V is pure of dimension d if thedimensions of the irreducible components are all equal to d .

Let W be a subvariety of a variety V . The codimension of W in V is

codimV W D dimV �dimW:

In �3 and �6 we proved the following results:

9.1. (a) The dimension of a linear subvariety of An (that is, a subvariety defined bylinear equations) has the value predicted by linear algebra (see 2.24b, 5.12). In par-ticular, dimAn D n. As a consequence, dimPn D n.

(b) Let Z be a proper closed subset of An; then Z has pure codimension one in An ifand only if I.Z/ is generated by a single nonconstant polynomial. Such a variety iscalled an affine hypersurface (see 2.25 and 2.27)1.

(c) If V is irreducible and Z is a proper closed subset of V , then dimZ < dimV (see2.26).

Affine varieties

The fundamental additional result that we need is that, when we impose additional poly-nomial conditions on an algebraic set, the dimension doesn’t go down by more than linearalgebra would suggest.

THEOREM 9.2. Let V be an irreducible affine variety, and let f a nonzero regular function.If f has a zero on V , then its zero set is pure of dimension dim.V /�1.

1The careful reader will check that we didn’t use 5.22 or 5.23 in the proof of 2.27.

155

156 9. DIMENSION THEORY

In other words: let V be a closed subvariety of An and let F 2 kŒX1; : : : ;Xn�; then

V \V.F /D

8<:V if F is identically zero on V; if F has no zeros on Vhypersurface otherwise.

where by hypersurface we mean a closed subvariety of pure codimension 1.We can also state it in terms of the algebras: let A be an affine k-algebra; let f 2 A

be neither zero nor a unit, and let p be a prime ideal that is minimal among those containing.f /; then

tr degkA=pD tr degkA�1:

LEMMA 9.3. Let A be an integral domain, and let L be a finite extension of the field offractions K of A. If ˛ 2 L is integral over A, then so also is NmL=K˛. Hence, if A isintegrally closed (e.g., if A is a unique factorization domain), then NmL=K˛ 2 A. In thislast case, ˛ divides NmL=K ˛ in the ring AŒ˛�.

PROOF. Let g.X/ be the minimum polynomial of ˛ over K;

g.X/DXrCar�1Xr�1C�� �Ca0:

In some extension field E of L, g.X/ will split

g.X/DQriD1.X �˛i /; ˛1 D ˛;

QriD1˛i D˙a0:

Because ˛ is integral overA, each ˛i is integral overA (see the proof of 1.22), and it followsthat NmL=K ˛

FT 5.41D .

QriD1˛i /

ŒLWK.˛/� is integral over A (see 1.16).Now suppose A is integrally closed, so that Nm˛ 2 A. From the equation

0D ˛.˛r�1Car�1˛r�2C�� �Ca1/Ca0

we see that ˛ divides a0 in AŒ˛�, and therefore it also divides Nm˛ D˙anr

0 . 2

PROOF (OF THEOREM 9.2). We first show that it suffices to prove the theorem in the casethat V.f / is irreducible. Suppose Z0; : : : ;Zn are the irreducible components of V.f /.There exists a point P 2Z0 that does not lie on any other Zi (otherwise the decompositionV.f /D

SZi would be redundant). As Z1; : : : ;Zn are closed, there is an open neighbour-

hood U of P , which we can take to be affine, that does not meet any Zi except Z0. NowV.f jU/DZ0\U , which is irreducible.

As V.f / is irreducible, rad.f / is a prime ideal p � kŒV �. According to the Noethernormalization theorem (8.13), there is a finite surjective map � WV ! Ad , which realizesk.V / as a finite extension of the field k.Ad /. We shall show that p\kŒAd �D rad.f0/wheref0 D Nmk.V /=k.Ad /f . Hence

kŒAd �=rad.f0/! kŒV �=p

is injective. As it is also finite, this shows that dimV.f /D dimV.f0/, and we already knowthe theorem for Ad (9.1b).

Affine varieties 157

By assumption kŒV � is finite (hence integral) over its subring kŒAd �. According to thelemma, f0 lies in kŒAd �, and I claim that p\kŒAd �D rad.f0/. The lemma shows that fdivides f0 in kŒV �, and so f0 2 .f /� p. Hence .f0/� p\kŒAd �, which implies

rad.f0/� p\kŒAd �

because p is radical. For the reverse inclusion, let g 2 p\kŒAd �. Then g 2 rad.f /, and sogm D f h for some h 2 kŒV �, m 2 N. Taking norms, we find that

gme D Nm.f h/D f0 �Nm.h/ 2 .f0/;

where e D Œk.V / W k.An/�, which proves the claim.The inclusion kŒAd � ,! kŒV � therefore induces an inclusion

kŒAd �= rad.f0/D kŒAd �=p\kŒAd � ,! kŒV �=p;

which makes kŒV �=p into a finite algebra over kŒAd �= rad.f0/. Hence

dimV.p/D dimV.f0/:

Clearly f ¤ 0)f0¤ 0, and f0 2 p)f0 is not a nonzero constant. Therefore dimV.f0/Dd �1 by (9.1b). 2

COROLLARY 9.4. Let V be an irreducible variety, and let Z be a maximal proper closedirreducible subset of V . Then dim.Z/D dim.V /�1.

PROOF. For any open affine subset U of V meeting Z, dimU D dimV and dimU \Z DdimZ. We may therefore assume that V itself is affine. Let f be a nonzero regular functionon V vanishing on Z, and let V.f / be the set of zeros of f (in V /. Then Z � V.f /� V ,and Z must be an irreducible component of V.f / for otherwise it wouldn’t be maximal inV . Thus Theorem 9.2 implies that dimZ D dimV �1. 2

COROLLARY 9.5 (TOPOLOGICAL CHARACTERIZATION OF DIMENSION). Suppose V isirreducible and that

V � V1 � �� � � Vd ¤ ;

is a maximal chain of distinct closed irreducible subsets of V . Then dim.V /D d . (Maximalmeans that the chain can’t be refined.)

PROOF. From (9.4) we find that

dimV D dimV1C1D dimV2C2D �� � D dimVd Cd D d: 2

REMARK 9.6. (a) The corollary shows that, when V is affine, dimV DKrull dimkŒV �, butit shows much more. Note that each Vi in a maximal chain (as above) has dimension d � i ,and that any closed irreducible subset of V of dimension d � i occurs as a Vi in a maximalchain. These facts translate into statements about ideals in affine k-algebras that do not holdfor all noetherian rings. For example, if A is an affine k-algebra that is an integral domain,then Krull dimAm is the same for all maximal ideals of A — all maximal ideals in A have

158 9. DIMENSION THEORY

the same height (we have proved 5.23). Moreover, if p is an ideal in kŒV � with height i ,then there is a maximal (i.e., nonrefinable) chain of distinct prime ideals

.0/� p1 � p2 � �� � � pd ¤ kŒV �

with pi D p.(b) Now that we know that the two notions of dimension coincide, we can restate (9.2)

as follows: let A be an affine k-algebra; let f 2 A be neither zero nor a unit, and let p be aprime ideal that is minimal among those containing .f /; then

Krull dim.A=p/D Krull dim.A/�1:

This statement holds for all noetherian local rings (CA 16.3), and is called Krull’s principalideal theorem.

COROLLARY 9.7. Let V be an irreducible variety, and let Z be an irreducible componentof V.f1; : : :fr/, where the fi are regular functions on V . Then

codim.Z/� r , i.e., dim.Z/� dimV � r:

For example, if the fi have no common zero on V , so that V.f1; : : : ;fr/ is empty, thenthere are no irreducible components, and the statement is vacuously true.

PROOF. As in the proof of (9.4), we can assume V to be affine. We use induction onr . Because Z is a closed irreducible subset of V.f1; : : :fr�1/, it is contained in someirreducible component Z0 of V.f1; : : :fr�1/. By induction, codim.Z0/ � r �1. Also Z isan irreducible component of Z0\V.fr/ because

Z �Z0\V.fr/� V.f1; : : : ;fr/

andZ is a maximal closed irreducible subset of V.f1; : : : ;fr/. If fr vanishes identically onZ0, then Z D Z0 and codim.Z/D codim.Z0/ � r � 1; otherwise, the theorem shows thatZ has codimension 1 in Z0, and codim.Z/D codim.Z0/C1� r . 2

PROPOSITION 9.8. Let V and W be closed subvarieties of An; for any (nonempty) irre-ducible component Z of V \W ,

dim.Z/� dim.V /Cdim.W /�nI

that is,codim.Z/� codim.V /C codim.W /:

PROOF. In the course of the proof of (4.27), we showed that V \W is isomorphic to �\.V �W /, and this is defined by the n equations Xi D Yi in V �W . Thus the statementfollows from (9.7). 2

REMARK 9.9. (a) The example (in A3)�X2CY 2 DZ2

Z D 0

Affine varieties 159

shows that Proposition 9.8 becomes false if one only looks at real points. Also, that thepictures we draw can mislead.

(b) The statement of (9.8) is false if An is replaced by an arbitrary affine variety. Con-sider for example the affine cone V

X1X4�X2X3 D 0:

It contains the planes,

Z WX2 D 0DX4I Z D f.�;0;�;0/g

Z0 WX1 D 0DX3I Z0 D f.0;�;0;�/g

andZ\Z0D f.0;0;0;0/g. Because V is a hypersurface inA4, it has dimension 3, and eachof Z and Z0 has dimension 2. Thus

codimZ\Z0 D 3� 1C1D codimZC codimZ0:

The proof of (9.8) fails because the diagonal in V �V cannot be defined by 3 equations(it takes the same 4 that define the diagonal in A4) — the diagonal is not a set-theoreticcomplete intersection.

REMARK 9.10. In (9.7), the components of V.f1; : : : ;fr/ need not all have the same di-mension, and it is possible for all of them to have codimension < r without any of the fibeing redundant.

For example, let V be the same affine cone as in the above remark. Note that V.X1/\Vis a union of the planes:

V.X1/\V D f.0;0;�;�/g[f.0;�;0;�/g:

Both of these have codimension 1 in V (as required by (9.2)). Similarly, V.X2/\V is theunion of two planes,

V.X2/\V D f.0;0;�;�/g[f.�;0;�;0/g;

but V.X1;X2/\V consists of a single plane f.0;0;�;�/g: it is still of codimension 1 in V ,but if we drop one of two equations from its defining set, we get a larger set.

PROPOSITION 9.11. LetZ be a closed irreducible subvariety of codimension r in an affinevariety V . Then there exist regular functions f1; : : : ;fr on V such that Z is an irreduciblecomponent of V.f1; : : : ;fr/ and all irreducible components of V.f1; : : : ;fr/ have codimen-sion r .

PROOF. We know that there exists a chain of closed irreducible subsets

V �Z1 � �� � �Zr DZ

with codim Zi D i . We shall show that there exist f1; : : : ;fr 2 kŒV � such that, for alls � r , Zs is an irreducible component of V.f1; : : : ;fs/ and all irreducible components ofV.f1; : : : ;fs/ have codimension s.

160 9. DIMENSION THEORY

We prove this by induction on s. For s D 1, take any f1 2 I.Z1/, f1 ¤ 0, and applyTheorem 9.2. Suppose f1; : : : ;fs�1 have been chosen, and let Y1 D Zs�1; : : : ;Ym, be theirreducible components of V.f1; : : : ;fs�1/. We seek an element fs that is identically zeroon Zs but is not identically zero on any Yi—for such an fs , all irreducible components ofYi\V.fs/will have codimension s, andZs will be an irreducible component of Y1\V.fs/.But Yi *Zs for any i (Zs has smaller dimension than Yi /, and so I.Zs/* I.Yi /. Now theprime avoidance lemma (see below) tells us that there is an element fs 2 I.Zs/ such thatfs … I.Yi / for any i , and this is the function we want. 2

LEMMA 9.12 (PRIME AVOIDANCE LEMMA). If an ideal a of a ring A is not contained inany of the prime ideals p1; : : : ;pr , then it is not contained in their union.

PROOF. We may assume that none of the prime ideals is contained in a second, becausethen we could omit it. Fix an i0 and, for each i ¤ i0, choose an fi 2 pi ; fi … pi0 , andchoose fi0 2 a, fi0 … pi0 . Then hi0

defDQfi lies in each pi with i ¤ i0 and a, but not in pi0

(here we use that pi0 is prime). The elementPriD1hi is therefore in a but not in any pi . 2

REMARK 9.13. The proposition shows that for a prime ideal p in an affine k-algebra, ifp has height r , then there exist elements f1; : : : ;fr 2 A such that p is minimal among theprime ideals containing .f1; : : : ;fr/. This statement is true for all noetherian local rings.

REMARK 9.14. The last proposition shows that a curve C in A3 is an irreducible com-ponent of V.f1;f2/ for some f1, f2 2 kŒX;Y;Z�. In fact C D V.f1;f2;f3/ for suitablepolynomials f1;f2, and f3 — this is an exercise in Shafarevich 1994 (I 6, Exercise 8; seealso Hartshorne 1977, I, Exercise 2.17). Apparently, it is not known whether two polynomi-als always suffice to define a curve in A3 — see Kunz 1985, p136. The union of two skewlines in P3 can’t be defined by two polynomials (ibid. p140), but it is unknown whetherall connected curves in P3 can be defined by two polynomials. Macaulay (the man, not theprogram) showed that for every r � 1, there is a curve C in A3 such that I.C / requiresat least r generators (see the same exercise in Hartshorne for a curve whose ideal can’t begenerated by 2 elements).

In general, a closed variety V of codimension r in An (resp. Pn/ is said to be a set-theoretic complete intersection if there exist r polynomials fi 2 kŒX1; : : : ;Xn� (resp. ho-mogeneous polynomials fi 2 kŒX0; : : : ;Xn�/ such that

V D V.f1; : : : ;fr/:

Such a variety is said to be an ideal-theoretic complete intersection if the fi can be chosenso that I.V /D .f1; : : : ;fr/. Chapter V of Kunz’s book is concerned with the question ofwhen a variety is a complete intersection. Obviously there are many ideal-theoretic com-plete intersections, but most of the varieties one happens to be interested in turn out notto be. For example, no abelian variety of dimension > 1 is an ideal-theoretic completeintersection (being an ideal-theoretic complete intersection imposes constraints on the co-homology of the variety, which are not fulfilled in the case of abelian varieties).2

2In 1882 Kronecker proved that every algebraic subset in Pn can be cut out by nC1 polynomial equations.In 1891 Vahlen asserted that the result was best possible by exhibiting a curve in P3 which he claimed was notthe zero locus of 3 equations. It was only 50 years later, in 1941, that Perron gave 3 equations defining Vahlen’s

Affine varieties 161

Let P be a point on an irreducible variety V � An. Then (9.11) shows that thereis a neighbourhood U of P in An and functions f1; : : : ;fr on U such that U \ V DV.f1; : : : ;fr/ (zero set in U/. Thus U \V is a set-theoretic complete intersection in U .One says that V is a local complete intersection at P 2 V if there is an open affine neigh-bourhood U of P in An such that I.V \U/ can be generated by r regular functions on U .Note that

ideal-theoretic complete intersection) local complete intersection at all p:

It is not difficult to show that a variety is a local complete intersection at every nonsingularpoint (cf. 5.17).

PROPOSITION 9.15. Let Z be a closed subvariety of codimension r in variety V , and letP be a point of Z that is nonsingular when regarded both as a point on Z and as a point onV . Then there is an open affine neighbourhood U of P and regular functions f1; : : : ;fr onU such that Z\U D V.f1; : : : ;fr/.

PROOF. By assumption

dimk TP .Z/D dimZ D dimV � r D dimk TP .V /� r:

There exist functions f1; : : : ;fr contained in the ideal of OP corresponding to Z such thatTP .Z/ is the subspace of TP .V / defined by the equations

.df1/P D 0; : : : ; .dfr/P D 0:

All the fi will be defined on some open affine neighbourhood U of P (in V ), and clearlyZ is the only component of Z0 def

D V.f1; : : : ;fr/ (zero set in U ) passing through P . Af-ter replacing U by a smaller neighbourhood, we can assume that Z0 is irreducible. Asf1; : : : ;fr 2 I.Z

0/, we must have TP .Z0/ � TP .Z/, and therefore dimZ0 � dimZ. ButI.Z0/� I.Z\U/, and so Z0 �Z\U . These two facts imply that Z0 DZ\U . 2

PROPOSITION 9.16. Let V be an affine variety such that kŒV � is a unique factorizationdomain. Then every pure closed subvariety Z of V of codimension one is principal, i.e.,I.Z/D .f / for some f 2 kŒV �.

PROOF. In (2.27) we proved this in the case that V D An, but the argument only used thatkŒAn� is a unique factorization domain. 2

EXAMPLE 9.17. The condition that kŒV � is a unique factorization domain is definitelyneeded. Again let V be the cone

X1X4�X2X3 D 0

in A4 and let Z and Z0 be the planes

Z D f.�;0;�;0/g Z0 D f.0;�;0;�/g:

curve, thus refuting Vahlen’s claim which had been accepted for half a century. Finally, in 1973 Eisenbud andEvans proved that n equations always suffice to describe (set-theoretically) any algebraic subset of Pn (GeorgesElencwajg on mathoverflow.net).

162 9. DIMENSION THEORY

Then Z\Z0 D f.0;0;0;0/g, which has codimension 2 in Z0. If Z D V.f / for some reg-ular function f on V , then V.f jZ0/ D f.0; : : : ;0/g, which is impossible (because it hascodimension 2, which violates 9.2). Thus Z is not principal, and so

kŒX1;X2;X3;X4�=.X1X4�X2X3/

is not a unique factorization domain.

Projective varieties

The results for affine varieties extend to projective varieties with one important simplifica-tion: if V and W are projective varieties of dimensions r and s in Pn and rC s � n, thenV \W ¤ ;.

THEOREM 9.18. Let V D V.a/ � Pn be a projective variety of dimension � 1, and letf 2 kŒX0; : : : ;Xn� be homogeneous, nonconstant, and … a; then V \V.f / is nonemptyand of pure codimension 1.

PROOF. Since the dimension of a variety is equal to the dimension of any dense open affinesubset, the only part that doesn’t follow immediately from (9.2) is the fact that V \V.f /is nonempty. Let V aff.a/ be the zero set of a in AnC1 (that is, the affine cone over V /.Then V aff.a/\V aff.f / is nonempty (it contains .0; : : : ;0/), and so it has codimension 1 inV aff.a/. Clearly V aff.a/ has dimension � 2, and so V aff.a/\V aff.f / has dimension � 1.This implies that the polynomials in a have a zero in common with f other than the origin,and so V.a/\V.f /¤ ;. 2

COROLLARY 9.19. Let f1; � � � ;fr be homogeneous nonconstant elements of kŒX0; : : : ;Xn�;and let Z be an irreducible component of V \V.f1; : : :fr/. Then codim.Z/ � r , and ifdim.V /� r , then V \V.f1; : : :fr/ is nonempty.

PROOF. Induction on r , as before. 2

COROLLARY 9.20. Let ˛WPn! Pm be regular; if m< n, then ˛ is constant.

PROOF. 3Let � WAnC1 � foriging ! Pn be the map .a0; : : : ;an/ 7! .a0 W : : : W an/. Then˛ ı� is regular, and there exist polynomials F0; : : : ;Fm 2 kŒX0; : : : ;Xn� such that ˛ ı� isthe map

.a0; : : : ;an/ 7! .F0.a/ W : : : W Fm.a//:

As ˛ ı� factors through Pn, the Fi must be homogeneous of the same degree. Note that

˛.a0 W : : : W an/D .F0.a/ W : : : W Fm.a//:

If m< n and the Fi are nonconstant, then (9.18) shows they have a common zero and so ˛is not defined on all of Pn. Hence the Fi ’s must be constant. 2

3Lars Kindler points out that, in this proof, it is not obvious that the map ˛ ı� is given globally by asystem of polynomials (rather than just locally). It is in fact given globally, and this is not too difficult to prove:a regular map from a variety V to Pn corresponds to a line bundle on V and a set of global sections, and all linebundles on An are trivial (see, for example, Hartshorne II 7.1 and II 6.2). I should fix this in a future version.

Projective varieties 163

PROPOSITION 9.21. Let Z be a closed irreducible subvariety of V ; if codim.Z/D r , thenthere exist homogeneous polynomials f1; : : : ;fr in kŒX0; : : : ;Xn� such that Z is an irre-ducible component of V \V.f1; : : : ;fr/.

PROOF. Use the same argument as in the proof (9.11). 2

PROPOSITION 9.22. Every pure closed subvariety Z of Pn of codimension one is princi-pal, i.e., I.Z/D .f / for some f homogeneous element of kŒX0; : : : ;Xn�.

PROOF. Follows from the affine case. 2

COROLLARY 9.23. Let V and W be closed subvarieties of Pn; if dim.V /Cdim.W / � n,then V \W ¤;, and every irreducible component of it has codim.Z/�codim.V /Ccodim.W /.

PROOF. Write V D V.a/ and W D V.b/, and consider the affine cones V 0 D V.a/ andW 0 D V.b/ over them. Then

dim.V 0/Cdim.W 0/D dim.V /C1Cdim.W /C1� nC2:

As V 0 \W 0 ¤ ;, V 0 \W 0 has dimension � 1, and so it contains a point other than theorigin. Therefore V \W ¤ ;. The rest of the statement follows from the affine case. 2

PROPOSITION 9.24. Let V be a closed subvariety of Pn of dimension r < n; then there is alinear projective varietyE of dimension n�r�1 (that is,E is defined by rC1 independentlinear forms) such that E\V D ;.

PROOF. Induction on r . If r D 0, then V is a finite set, and the lemma below shows thatthere is a hyperplane in knC1 not meeting V .

Suppose r > 0, and let V1; : : : ;Vs be the irreducible components of V . By assumption,they all have dimension � r . The intersection Ei of all the linear projective varieties con-taining Vi is the smallest such variety. The lemma below shows that there is a hyperplaneHcontaining none of the nonzero Ei ; consequently, H contains none of the irreducible com-ponents Vi of V , and so each Vi \H is a pure variety of dimension � r �1 (or is empty).By induction, there is an linear subvariety E 0 not meeting V \H . Take E DE 0\H . 2

LEMMA 9.25. Let W be a vector space of dimension d over an infinite field k, and letE1; : : : ;Er be a finite set of nonzero subspaces of W . Then there is a hyperplane H in Wcontaining none of the Ei .

PROOF. Pass to the dual space V of W . The problem becomes that of showing V is nota finite union of proper subspaces E_i . Replace each E_i by a hyperplane Hi containingit. Then Hi is defined by a nonzero linear form Li . We have to show that

QLj is not

identically zero on V . But this follows from the statement that a polynomial in n variables,with coefficients not all zero, can not be identically zero on kn (Exercise 1-1). 2

Let V and E be as in Proposition 9.24. If E is defined by the linear forms L0; : : : ;Lrthen the projection a 7! .L0.a/ W � � � W Lr.a// defines a map V ! Pr . We shall see laterthat this map is finite, and so it can be regarded as a projective version of the Noethernormalization theorem.

CHAPTER 10Regular Maps and Their Fibres

Throughout this chapter, k is an algebraically closed field.Consider again the regular map 'WA2 ! A2, .x;y/ 7! .x;xy/ (Exercise 3-3). The

image of ' is

C D f.a;b/ 2 A2 j a¤ 0 or aD 0D bg

D .A2r fy-axisg/[f.0;0/g;

which is neither open nor closed, and, in fact, is not even locally closed. The fibre

'�1.a;b/D

8<:f.a;b=a/g if a¤ 0Y -axis if .a;b/D .0;0/; if aD 0, b ¤ 0:

From this unpromising example, it would appear that it is not possible to say anything aboutthe image of a regular map, nor about the dimension or number of elements in its fibres.However, it turns out that almost everything that can go wrong already goes wrong for thismap. We shall show:

(a) the image of a regular map is a finite union of locally closed sets;(b) the dimensions of the fibres can jump only over closed subsets;(c) the number of elements (if finite) in the fibres can drop only on closed subsets, pro-

vided the map is finite, the target variety is normal, and k has characteristic zero.

Constructible sets

LetW be a topological space. A subset C ofW is said to constructible if it is a finite unionof sets of the form U \Z with U open and Z closed. Obviously, if C is constructibleand V �W , then C \V is constructible. A constructible set in An is definable by a finitenumber of polynomials; more precisely, it is defined by a finite number of statements of theform

f .X1; � � � ;Xn/D 0; g.X1; � � � ;Xn/¤ 0

combined using only “and” and “or” (or, better, statements of the form f D 0 combinedusing “and”, “or”, and “not”). The next proposition shows that a constructible set C thatis dense in an irreducible variety V must contain a nonempty open subset of V . ContrastQ, which is dense in R (real topology), but does not contain an open subset of R, or anyinfinite subset of A1 that omits an infinite set.

165

166 10. REGULAR MAPS AND THEIR FIBRES

PROPOSITION 10.1. Let C be a constructible set whose closure NC is irreducible. Then Ccontains a nonempty open subset of NC .

PROOF. We are given that C DS.Ui \Zi / with each Ui open and each Zi closed. We

may assume that each set Ui \Zi in this decomposition is nonempty. Clearly NC �SZi ,

and as NC is irreducible, it must be contained in one of the Zi . For this i

C � Ui \Zi � Ui \ NC � Ui \C � Ui \ .Ui \Zi /D Ui \Zi :

Thus Ui \Zi D Ui \ NC is a nonempty open subset of NC contained in C . 2

THEOREM 10.2. A regular map 'WW ! V sends constructible sets to constructible sets.In particular, if U is a nonempty open subset of W , then '.U / contains a nonempty opensubset of its closure in V .

The key result we shall need from commutative algebra is the following. (In the nexttwo results, A and B are arbitrary commutative rings—they need not be k-algebras.)

PROPOSITION 10.3. LetA�B be integral domains withB finitely generated as an algebraover A, and let b be a nonzero element of B . Then there exists an element a ¤ 0 in Awith the following property: every homomorphism ˛WA!˝ from A into an algebraicallyclosed field˝ such that ˛.a/¤ 0 can be extended to a homomorphism ˇWB!˝ such thatˇ.b/¤ 0.

Consider, for example, the rings kŒX� � kŒX;X�1�. A homomorphism ˛WkŒX�! k

extends to a homomorphism kŒX;X�1�! k if and only if ˛.X/¤ 0. Therefore, for b D 1,we can take aDX . In the application we make of Proposition 10.3, we only really need thecase b D 1, but the more general statement is needed so that we can prove it by induction.

LEMMA 10.4. Let B �A be integral domains, and assume B DAŒt��AŒT �=a. Let c�Abe the set of leading coefficients of the polynomials in a. Then every homomorphism˛WA!˝ from A into an algebraically closed field ˝ such that ˛.c/¤ 0 can be extendedto a homomorphism of B into ˝.

PROOF. Note that c is an ideal in A. If aD 0, then cD 0, and there is nothing to prove (infact, every ˛ extends). Thus we may assume a¤ 0. Let f D amTmC�� �Ca0 be a nonzeropolynomial of minimum degree in a such that ˛.am/ ¤ 0. Because B ¤ 0, we have thatm� 1.

Extend ˛ to a homomorphism Q WAŒT �!˝ŒT � by sending T to T . The ˝-submoduleof ˝ŒT � generated by Q .a/ is an ideal (because T �

Pci Q .gi /D

Pci Q .giT //. Therefore,

unless Q .a/ contains a nonzero constant, it generates a proper ideal in ˝ŒT �, which willhave a zero c in ˝. The homomorphism

AŒT �e!˝ŒT �!˝; T 7! T 7! c

then factors through AŒT �=aD B and extends ˛.In the contrary case, a contains a polynomial

g.T /D bnTnC�� �Cb0; ˛.bi /D 0 .i > 0/; ˛.b0/¤ 0:

Constructible sets 167

On dividing f .T / into g.T / we find that

admg.T /D q.T /f .T /C r.T /; d 2 N; q;r 2 AŒT �; degr < m:

On applying Q to this equation, we obtain

˛.am/d˛.b0/D Q .q/ Q .f /C Q .r/:

Because Q .f / has degreem>0, we must have Q .q/D 0, and so Q .r/ is a nonzero constant.After replacing g.T / with r.T /, we may assume n <m. If mD 1, such a g.T / can’t exist,and so we may suppose m > 1 and (by induction) that the lemma holds for smaller valuesof m.

For h.T / D crT r C cr�1T r�1C �� � C c0, let h0.T / D cr C �� � C c0T r . Then the A-module generated by the polynomials T sh0.T /, s � 0, h 2 a, is an ideal a0 in AŒT �. More-over, a0 contains a nonzero constant if and only if a contains a nonzero polynomial cT r ,which implies t D 0 and AD B (since B is an integral domain).

If a0 does not contain nonzero constants, then set B 0 D AŒT �=a0 D AŒt 0�. Then a0 con-tains the polynomial g0 D bnC�� �Cb0T n, and ˛.b0/¤ 0. Because degg0 <m, the induc-tion hypothesis implies that ˛ extends to a homomorphism B 0!˝. Therefore, there is ac 2˝ such that, for all h.T /D crT rC cr�1T r�1C�� �C c0 2 a,

h0.c/D ˛.cr/C˛.cr�1/cC�� �C c0crD 0:

On taking h D g, we see that c D 0, and on taking h D f , we obtain the contradiction˛.am/D 0. 2

PROOF (OF 10.3) Suppose that we know the proposition in the case that B is generatedby a single element, and write B D AŒx1; : : : ;xn�. Then there exists an element bn�1 suchthat any homomorphism ˛WAŒx1; : : : ;xn�1�!˝ such that ˛.bn�1/¤ 0 extends to a homo-morphism ˇWB!˝ such that ˇ.b/¤ 0. Continuing in this fashion, we obtain an elementa 2 A with the required property.

Thus we may assume B D AŒx�. Let a be the kernel of the homomorphism X 7! x,AŒX�! AŒx�.

Case (i). The ideal aD .0/. Write

b D f .x/D a0xnCa1x

n�1C�� �Can; ai 2 A;

and take a D a0. If ˛WA!˝ is such that ˛.a0/¤ 0, then there exists a c 2˝ such thatf .c/¤ 0, and we can take ˇ to be the homomorphism

Pdix

i 7!P˛.di /c

i .Case (ii). The ideal a ¤ .0/. Let f .T / D amTmC �� � , am ¤ 0, be an element of a

of minimum degree. Let h.T / 2 AŒT � represent b. Since b ¤ 0, h … a. Because f isirreducible over the field of fractions of A, it and h are coprime over that field. Hence thereexist u;v 2 AŒT � and c 2 A�f0g such that

uhCvf D c:

It follows now that cam satisfies our requirements, for if ˛.cam/ ¤ 0, then ˛ can be ex-tended to ˇWB!˝ by the previous lemma, and ˇ.u.x/ �b/D ˇ.c/¤ 0, and so ˇ.b/¤ 0.2

168 10. REGULAR MAPS AND THEIR FIBRES

ASIDE 10.5. In case (ii) of the above proof, both b and b�1 are algebraic over A, and sothere exist equations

a0bmC�� �Cam D 0; ai 2 A; a0 ¤ 0I

a00b�nC�� �Ca0n D 0; a0i 2 A; a00 ¤ 0:

One can show that aD a0a00 has the property required by the Proposition—see Atiyah andMacDonald, 5.23.

PROOF (OF 10.2) We first prove the “in particular” statement of the Theorem. By consid-ering suitable open affine coverings ofW and V , one sees that it suffices to prove this in thecase that bothW and V are affine. IfW1; : : : ;Wr are the irreducible components ofW , thenthe closure of '.W / in V , '.W /� D '.W1/�[ : : :['.Wr/�, and so it suffices to provethe statement in the case thatW is irreducible. We may also replace V with '.W /�, and soassume that both W and V are irreducible. Then ' corresponds to an injective homomor-phism A!B of affine k-algebras. For some b ¤ 0, D.b/� U . Choose a as in the lemma.Then for any point P 2D.a/, the homomorphism f 7! f .P /WA! k extends to a homo-morphism ˇWB! k such that ˇ.b/¤ 0. The kernel of ˇ is a maximal ideal correspondingto a point Q 2D.b/ lying over P .

We now prove the theorem. Let Wi be the irreducible components of W . Then C \Wiis constructible inWi , and '.W / is the union of the '.C \Wi /; it is therefore constructibleif the '.C \Wi / are. Hence we may assume that W is irreducible. Moreover, C is afinite union of its irreducible components, and these are closed in C ; they are thereforeconstructible. We may therefore assume that C also is irreducible; NC is then an irreducibleclosed subvariety of W .

We shall prove the theorem by induction on the dimension of W . If dim.W /D 0, thenthe statement is obvious because W is a point. If NC ¤ W , then dim. NC/ < dim.W /, andbecause C is constructible in NC , we see that '.C / is constructible (by induction). We maytherefore assume that NC DW . But then NC contains a nonempty open subset of W , and sothe case just proved shows that '.C / contains an nonempty open subset U of its closure.Replace V be the closure of '.C /, and write

'.C /D U ['.C \'�1.V �U//:

Then '�1.V �U/ is a proper closed subset of W (the complement of V �U is densein V and ' is dominant). As C \ '�1.V �U/ is constructible in '�1.V �U/, the set'.C \'�1.V �U// is constructible in V by induction, which completes the proof. 2

Orbits of group actions

Let G be an algebraic group. An action of G on a variety V is a regular map

.g;P / 7! gP WG�V ! V

such that

(a) 1GP D P , all P 2 V ;(b) g.g0P /D .gg0/P , all g;g0 2G, P 2 V .

Orbits of group actions 169

PROPOSITION 10.6. Let G�V ! V be an action of an algebraic group G on a variety V .

(a) Each orbit of G in X is open in its closure.(b) There exist closed orbits.

PROOF. (a) Let O be an orbit of G in V and let P 2 O . Then g 7! gP WG ! V is aregular map with image O , and so O contains a nonempty set U open in NO (10.2). AsO D

Sg2G.k/gU , it is open in NO .

(b) Let S D NO be minimal among the closures of orbits. From (a), we know that O isopen in S . Therefore, if S rO were nonempty, it would contain the closure of an orbit,contradicting the minimality of S . Hence S DO . 2

Let G be an algebraic group acting on a variety V . Let GnV denote the quotienttopological space with the sheaf OGnV such that � .U;OGnV /D � .��1U;OV /G , where� WG!G=V is the quotient map. When .GnV;OGnV / is a variety, we call it the geometricquotient of V under the action of G.

PROPOSITION 10.7. Let N be a normal algebraic subgroup of an affine algebraic groupG. Then the geometric quotient of G by N exists, and is an affine algebraic group.

PROOF. Omitted for the present. 2

A connected affine algebraic group G is solvable if there exist connected algebraicsubgroups

G DGd �Gd�1 � �� � �G0 D f1g

such that Gi is normal in GiC1, and Gi=GiC1 is commutative.

THEOREM 10.8 (BOREL FIXED POINT THEOREM). A connected solvable affine algebraicgroup G acting on a complete algebraic variety V has at least one fixed point.

PROOF. We prove this by induction on the dimG. Assume first that G is commutative, andlet O DGx be a closed orbit of G in V (see 10.6). Let N be the stabilizer of x. Because Gis commutative, N is normal, and we get a bijection G=N !O . As G acts transitively onG=N and O , the map G=N !O is proper (see Exercise 10-4); as O is complete (7.3a), soalso is G=N (see 8.24), and as it is affine and connected, it consists of a single point (7.5).Therefore, O consists of a single point, which is a fixed point for the action.

By assumption, there exists a closed normal subgroup H of G such that G=H is acommutative. The set XH of fixed points ofH in X is nonempty (by induction) and closed(because it is the intersection of the sets

Xh D fx 2X j hx D xg

for h 2H ). Because H is normal, XH is stable under G, and the action of G on it factorsthrough G=H . Every fixed point of G=H in XH is a fixed point for G acting on X . 2

170 10. REGULAR MAPS AND THEIR FIBRES

The fibres of morphisms

We wish to examine the fibres of a regular map 'WW ! V . Clearly, we can replace V bythe closure of '.W / in V and so assume ' to be dominant.

THEOREM 10.9. Let 'WW ! V be a dominant regular map of irreducible varieties. Then

(a) dim.W /� dim.V /;(b) if P 2 '.W /, then

dim.'�1.P //� dim.W /�dim.V /

for every P 2 V , with equality holding exactly on a nonempty open subset U of V .(c) The sets

Vi D fP 2 V j dim.'�1.P //� ig

are closed in '.W /.

EXAMPLE 10.10. Consider the subvariety W � V �Am defined by r linear equations

mXjD1

aijXj D 0; aij 2 kŒV �; i D 1; : : : ; r;

and let ' be the projection W ! V . For P 2 V , '�1.P / is the set of solutions of

mXjD1

aij .P /Xj D 0; aij .P / 2 k; i D 1; : : : ; r;

and so its dimension is m� rank.aij .P //. Since the rank of the matrix .aij .P // drops onclosed subsets, the dimension of the fibre jumps on closed subsets.

PROOF. (a) Because the map is dominant, there is a homomorphism k.V / ,! k.W /, andobviously tr degkk.V / � tr degkk.W / (an algebraically independent subset of k.V / re-mains algebraically independent in k.W /).

(b) In proving the first part of (b), we may replace V by any open neighbourhood of P .In particular, we can assume V to be affine. Let m be the dimension of V . From (9.11) weknow that there exist regular functions f1; : : : ;fm such that P is an irreducible componentof V.f1; : : : ;fm/. After replacing V by a smaller neighbourhood of P , we can suppose thatP D V.f1; : : : ;fm/. Then '�1.P / is the zero set of the regular functions f1 ı'; : : : ;fm ı',and so (if nonempty) has codimension �m in W (see 9.7). Hence

dim'�1.P /� dimW �mD dim.W /�dim.V /:

In proving the second part of (b), we can replace both W and V with open affine sub-sets. Since ' is dominant, kŒV �! kŒW � is injective, and we may regard it as an in-clusion (we identify a function x on V with x ı ' on W /. Then k.V / � k.W /. WritekŒV �D kŒx1; : : : ;xM � and kŒW �D kŒy1; : : : ;yN �, and suppose V and W have dimensionsm and n respectively. Then k.W / has transcendence degree n�m over k.V /, and we maysuppose that y1; : : : ;yn�m are algebraically independent over kŒx1; : : : ;xm�, and that theremaining yi are algebraic over kŒx1; : : : ;xm;y1; : : : ;yn�m�. There are therefore relations

Fi .x1; : : : ;xm;y1; : : : ;yn�m;yi /D 0; i D n�mC1; : : : ;N: (25)

The fibres of morphisms 171

with Fi .X1; : : : ;Xm;Y1; : : : ;Yn�m;Yi / a nonzero polynomial. We write Nyi for the restric-tion of yi to '�1.P /. Then

kŒ'�1.P /�D kŒ Ny1; : : : ; NyN �:

The equations (25) give an algebraic relation among the functions x1; : : : ;yi on W . Whenwe restrict them to '�1.P /, they become equations:

Fi .x1.P /; : : : ;xm.P /; Ny1; : : : ; Nyn�m; Nyi /D 0; i D n�mC1; : : : ;N:

If these are nontrivial algebraic relations, i.e., if none of the polynomials

Fi .x1.P /; : : : ;xm.P /;Y1; : : : ;Yn�m;Yi /

is identically zero, then the transcendence degree of k. Ny1; : : : ; NyN / over k will be � n�m.Thus, regard Fi .x1; : : : ;xm;Y1; : : : ;Yn�m;Yi / as a polynomial in the Y ’s with coeffi-

cients polynomials in the x’s. Let Vi be the closed subvariety of V defined by the simul-taneous vanishing of the coefficients of this polynomial—it is a proper closed subset of V .Let U D V �

SVi—it is a nonempty open subset of V . If P 2 U , then none of the poly-

nomials Fi .x1.P /; : : : ;xm.P /;Y1; : : : ;Yn�m;Yi / is identically zero, and so for P 2 U , thedimension of '�1.P / is � n�m, and henceD n�m by (a).

Finally, if for a particular point P , dim'�1.P /D n�m, then one can modify the aboveargument to show that the same is true for all points in an open neighbourhood of P .

(c) We prove this by induction on the dimension of V—it is obviously true if dimV D 0.We know from (b) that there is an open subset U of V such that

dim'�1.P /D n�m ” P 2 U:

Let Z be the complement of U in V ; thus Z D Vn�mC1. Let Z1; : : : ;Zr be the irreduciblecomponents of Z. On applying the induction to the restriction of ' to the map '�1.Zj /!Zj for each j , we obtain the result. 2

PROPOSITION 10.11. Let 'WW ! V be a regular surjective closed mapping of varieties(e.g., W complete or ' finite). If V is irreducible and all the fibres '�1.P / are irreducibleof dimension n, then W is irreducible of dimension dim.V /Cn.

PROOF. Let Z be a closed irreducible subset of W , and consider the map 'jZWZ! V ; ithas fibres .'jZ/�1.P /D '�1.P /\Z. There are three possibilities.

(a) '.Z/¤ V . Then '.Z/ is a proper closed subset of V .(b) '.Z/D V , dim.Z/ < nCdim.V /. Then (b) of (10.9) shows that there is a nonempty

open subset U of V such that for P 2 U ,

dim.'�1.P /\Z/D dim.Z/�dim.V / < nI

thus for P 2 U , '�1.P /*Z.(c) '.Z/D V , dim.Z/� nCdim.V /. Then (b) of (10.9) shows that

dim.'�1.P /\Z/� dim.Z/�dim.V /� n

for all P ; thus '�1.P /�Z for all P 2 V , and so Z DW ; moreover dimZ D n.

Now let Z1; : : : ;Zr be the irreducible components of W . I claim that (c) holds for atleast one of the Zi . Otherwise, there will be an open subset U of V such that for P in U ,'�1.P / * Zi for any i , but '�1.P / is irreducible and '�1.P /D

S.'�1.P /\Zi /, and

so this is impossible. 2

172 10. REGULAR MAPS AND THEIR FIBRES

The fibres of finite maps

Let 'WW ! V be a finite dominant morphism of irreducible varieties. Then dim.W / Ddim.V /, and so k.W / is a finite field extension of k.V /. Its degree is called the degree ofthe map '.

THEOREM 10.12. Let 'WW ! V be a finite surjective regular map of irreducible varieties,and assume that V is normal.

(a) For all P 2 V , #'�1.P /� deg.'/.(b) The set of points P of V such that #'�1.P /D deg.'/ is an open subset of V , and it

is nonempty if k.W / is separable over k.V /.

Before proving the theorem, we give examples to show that we need W to be separatedand V to be normal in (a), and that we need k.W / to be separable over k.V / for the secondpart of (b).

EXAMPLE 10.13. (a) Consider the map

fA1 with origin doubled g ! A1:

The degree is one and that map is one-to-one except at the origin where it is two-to-one.(b) Let C be the curve Y 2 DX3CX2, and consider the map

t 7! .t2�1; t.t2�1//WA1! C .

It is one-to-one except that the points t D˙1 both map to 0. On coordinate rings, it corre-sponds to the inclusion

kŒx;y� ,! kŒT �, x 7! T 2�1, y 7! T .T 2�1/;

and so is of degree one. The ring kŒx;y� is not integrally closed; in fact kŒT � is its integralclosure in its field of fractions.

(c) Consider the Frobenius map 'WAn! An, .a1; : : : ;an/ 7! .ap1 ; : : : ;a

pn /, where p D

chark. This map has degree pn but it is one-to-one. The field extension corresponding tothe map is

k.X1; : : : ;Xn/� k.Xp1 ; : : : ;X

pn /

which is purely inseparable.

LEMMA 10.14. Let Q1; : : : ;Qr be distinct points on an affine variety V . Then there is aregular function f on V taking distinct values at the Qi .

PROOF. We can embed V as closed subvariety of An, and then it suffices to prove thestatement with V D An — almost any linear form will do. 2

PROOF (OF 10.12). In proving (a) of the theorem, we may assume that V andW are affine,and so the map corresponds to a finite map of k-algebras, kŒV �! kŒW �. Let '�1.P / DfQ1; : : : ;Qrg. According to the lemma, there exists an f 2 kŒW � taking distinct values atthe Qi . Let

F.T /D TmCa1Tm�1C�� �Cam

Flat maps 173

be the minimum polynomial of f over k.V /. It has degree m � Œk.W / W k.V /� D deg',and it has coefficients in kŒV � because V is normal (see 1.22). Now F.f / D 0 impliesF.f .Qi //D 0, i.e.,

f .Qi /mCa1.P / �f .Qi /

m�1C�� �Cam.P /D 0:

Therefore the f .Qi / are all roots of a single polynomial of degree m, and so r � m �deg.'/.

In order to prove the first part of (b), we show that, if there is a point P 2 V such that'�1.P / has deg.'/ elements, then the same is true for all points in an open neighbourhoodof P . Choose f as in the last paragraph corresponding to such a P . Then the polynomial

TmCa1.P / �Tm�1C�� �Cam.P /D 0 (*)

has r D deg' distinct roots, and somD r . Consider the discriminant discF of F . Because(*) has distinct roots, disc.F /.P /¤ 0, and so disc.F / is nonzero on an open neighbourhoodU of P . The factorization

kŒV �! kŒV �ŒT �=.F /T 7!f! kŒW �

gives a factorizationW ! Spm.kŒV �ŒT �=.F //! V:

Each point P 0 2U has exactlym inverse images under the second map, and the first map isfinite and dominant, and therefore surjective (recall that a finite map is closed). This provesthat '�1.P 0/ has at least deg.'/ points for P 0 2U , and part (a) of the theorem then impliesthat it has exactly deg.'/ points.

We now show that if the field extension is separable, then there exists a point suchthat #'�1.P / has deg' elements. Because k.W / is separable over k.V /, there exists af 2 kŒW � such that k.V /Œf �D k.W /. Its minimum polynomial F has degree deg.'/ andits discriminant is a nonzero element of kŒV �. The diagram

W ! Spm.AŒT �=.F //! V

shows that #'�1.P /� deg.'/ for P a point such that disc.f /.P /¤ 0. 2

When k.W / is separable over k.V /, then ' is said to be separable.

REMARK 10.15. Let 'WW !V be as in the theorem, and let Vi DfP 2V j #'�1.P /� ig:Let d D deg': Part (b) of the theorem states that Vd�1 is closed, and is a proper subset when' is separable. I don’t know under what hypotheses all the sets Vi will closed (and Vi willbe a proper subset of Vi�1). The obvious induction argument fails because Vi�1 may notbe normal.

Flat maps

A regular map 'WV !W is flat if for all P 2 V , the homomorphism O'.P /!OP definedby ' is flat. If ' is flat, then for every pair U and U 0 of open affines of V and W such that'.U /�U 0 the map � .U 0;OW /! � .U;OV / is flat; conversely, if this condition holds forsufficiently many pairs that the U ’s cover V and the U 0’s cover W , then ' is flat.

174 10. REGULAR MAPS AND THEIR FIBRES

PROPOSITION 10.16. (a) An open immersion is flat.(b) The composite of two flat maps is flat.(c) Any base extension of a flat map is flat.

PROOF. To be added. 2

THEOREM 10.17. A finite map 'WV !W is flat if and only ifXQ 7!P

dimkOQ=mPOQ

is independent of P 2W .

PROOF. To be added. 2

THEOREM 10.18. Let V and W be irreducible varieties. If 'WV !W is flat, then

dim'�1.Q/D dimV �dimW (26)

for all Q 2W . Conversely, if V and W are nonsingular and (26) holds for all Q 2W , then' is flat.

PROOF. To be added. 2

Lines on surfaces

As an application of some of the above results, we consider the problem of describing theset of lines on a surface of degree m in P3. To avoid possible problems, we assume for therest of this chapter that k has characteristic zero.

We first need a way of describing lines in P3. Recall that we can associate with eachprojective variety V � Pn an affine cone over QV in knC1. This allows us to think of pointsin P3 as being one-dimensional subspaces in k4, and lines in P3 as being two-dimensionalsubspaces in k4. To such a subspace W � k4, we can attach a one-dimensional subspaceV2

W inV2

k4 � k6, that is, to each line L in P3, we can attach point p.L/ in P5. Notevery point in P5 should be of the form p.L/—heuristically, the lines in P3 should form afour-dimensional set. (Fix two planes in P3; giving a line in P3 corresponds to choosing apoint on each of the planes.) We shall show that there is natural one-to-one correspondencebetween the set of lines in P3 and the set of points on a certain hyperspace ˘ � P5. Ratherthan using exterior algebras, I shall usually give the old-fashioned proofs.

Let L be a line in P3 and let xD .x0 W x1 W x2 W x3/ and yD .y0 W y1 W y2 W y3/ be distinctpoints on L. Then

p.L/D .p01 W p02 W p03 W p12 W p13 W p23/ 2 P5; pijdefD

ˇxi xjyi yj

ˇ;

depends only on L. The pij are called the Plucker coordinates of L, after Plucker (1801-1868).

In terms of exterior algebras, write e0, e1, e2, e3 for the canonical basis for k4, so that x,regarded as a point of k4 is

Pxiei , and yD

Pyiei ; then

V2k4 is a 6-dimensional vector

Lines on surfaces 175

space with basis ei^ej , 0� i < j � 3, and x^y DPpij ei^ej with pij given by the above

formula.We define pij for all i;j , 0� i;j � 3 by the same formula — thus pij D�pj i .

LEMMA 10.19. The line L can be recovered from p.L/ as follows:

LD f.Pj ajp0j W

Pj ajp1j W

Pj ajp2j W

Pj ajp3j / j .a0 W a1 W a2 W a3/ 2 P3g:

PROOF. Let QL be the cone over L in k4—it is a two-dimensional subspace of k4—and letxD .x0;x1;x2;x3/ and yD .y0;y1;y2;y3/ be two linearly independent vectors in QL. Then

QLD ff .y/x�f .x/y j f Wk4! k linearg:

Write f DPajXj ; then

f .y/x�f .x/yD .Pajp0j ;

Pajp1j ;

Pajp2j ;

Pajp3j /: 2

LEMMA 10.20. The point p.L/ lies on the quadric ˘ � P5 defined by the equation

X01X23�X02X13CX03X12 D 0:

PROOF. This can be verified by direct calculation, or by using that

0D

ˇˇ x0 x1 x2 x3y0 y1 y2 y3x0 x1 x2 x3y0 y1 y2 y3

ˇˇD 2.p01p23�p02p13Cp03p12/

(expansion in terms of 2�2 minors). 2

LEMMA 10.21. Every point of ˘ is of the form p.L/ for a unique line L.

PROOF. Assume p03 ¤ 0; then the line through the points .0 W p01 W p02 W p03/ and .p03 Wp13 W p23 W 0/ has Plucker coordinates

.�p01p03 W �p02p03 W �p203 W p01p23�p02p13„ ƒ‚ …

�p03p12

W �p03p13 W �p03p23/

D .p01 W p02 W p03 W p12 W p13 W p23/:

A similar construction works when one of the other coordinates is nonzero, and this waywe get inverse maps. 2

Thus we have a canonical one-to-one correspondence

flines in P3g $ fpoints on ˘gI

that is, we have identified the set of lines in P3 with the points of an algebraic variety. Wemay now use the methods of algebraic geometry to study the set. (This is a special case ofthe Grassmannians discussed in �6.)

We next consider the set of homogeneous polynomials of degree m in 4 variables,

F.X0;X1;X2;X3/DX

i0Ci1Ci2Ci3Dm

ai0i1i2i3Xi00 : : :X

i33 :

176 10. REGULAR MAPS AND THEIR FIBRES

LEMMA 10.22. The set of homogeneous polynomials of degreem in 4 variables is a vectorspace of dimension

�3Cmm

�PROOF. See the footnote p126. 2

Let � D�3Cmm

��1D .mC1/.mC2/.mC3/

6� 1, and regard P� as the projective space at-

tached to the vector space of homogeneous polynomials of degree m in 4 variables (p130).Then we have a surjective map

P�! fsurfaces of degree m in P3g;

.: : : W ai0i1i2i3 W : : :/ 7! V.F /; F DX

ai0i1i2i3Xi00 X

i11 X

i22 X

i33 :

The map is not quite injective—for example, X2Y and XY 2 define the same surface—but nevertheless, we can (somewhat loosely) think of the points of P� as being (possiblydegenerate) surfaces of degree m in P3.

Let �m �˘ �P� � P5�P� be the set of pairs .L;F / consisting of a line L in P3 lyingon the surface F.X0;X1;X2;X3/D 0.

THEOREM 10.23. The set �m is a closed irreducible subset of ˘ �P� ; it is therefore aprojective variety. The dimension of �m is m.mC1/.mC5/

6C3.

EXAMPLE 10.24. For mD 1; �m is the set of pairs consisting of a plane in P3 and a lineon the plane. The theorem says that the dimension of �1 is 5. Since there are13 planes inP3, and each has12 lines on it, this seems to be correct.

PROOF. We first show that �m is closed. Let

p.L/D .p01 W p02 W : : :/ F DX

ai0i1i2i3Xi00 � � �X

i33 :

From (10.19) we see that L lies on the surface F.X0;X1;X2;X3/D 0 if and only if

F.Pbjp0j W

Pbjp1j W

Pbjp2j W

Pbjp3j /D 0, all .b0; : : : ;b3/ 2 k4:

Expand this out as a polynomial in the bj ’s with coefficients polynomials in the ai0i1i2i3and pij ’s. Then F.:::/D 0 for all b 2 k4 if and only if the coefficients of the polynomialare all zero. But each coefficient is of the form

P.: : : ;ai0i1i2i3 ; : : : Ip01;p02 W : : :/

with P homogeneous separately in the a’s and p’s, and so the set is closed in ˘ �P� (cf.the discussion in 7.9).

It remains to compute the dimension of �m. We shall apply Proposition 10.11 to theprojection map

.L;F / �m �˘ �P�

L ˘

'

Lines on surfaces 177

For L 2˘ , '�1.L/ consists of the homogeneous polynomials of degree m such that L �V.F / (taken up to nonzero scalars). After a change of coordinates, we can assume that Lis the line �

X0 D 0

X1 D 0;

i.e.,LDf.0;0;�;�/g. ThenL lies on F.X0;X1;X2;X3/D 0 if and only ifX0 orX1 occursin each nonzero monomial term in F , i.e.,

F 2 '�1.L/ ” ai0i1i2i3 D 0 whenever i0 D 0D i1:

Thus '�1.L/ is a linear subspace of P� ; in particular, it is irreducible. We now compute itsdimension. Recall that F has �C1 coefficients altogether; the number with i0 D 0D i1 ismC1, and so '�1.L/ has dimension

.mC1/.mC2/.mC3/

6�1� .mC1/D

m.mC1/.mC5/

6�1:

We can now deduce from (10.11) that �m is irreducible and that

dim.�m/D dim.˘/Cdim.'�1.L//Dm.mC1/.mC5/

6C3;

as claimed. 2

Now consider the other projection By definition

�1.F /D fL j L lies on V.F /g:

EXAMPLE 10.25. Let mD 1. Then � D 3 and dim�1 D 5. The projection W�1! P3 issurjective (every plane contains at least one line), and (10.9) tells us that dim �1.F / � 2.In fact of course, the lines on any plane form a 2-dimensional family, and so �1.F /D 2for all F .

THEOREM 10.26. Whenm> 3, the surfaces of degreem containing no line correspond toan open subset of P� .

PROOF. We have

dim�m�dimP� Dm.mC1/.mC5/

6C3�

.mC1/.mC2/.mC3/

6C1D 4� .mC1/:

Therefore, if m> 3, then dim�m < dimP� , and so .�m/ is a proper closed subvariety ofP� . This proves the claim. 2

We now look at the case mD 2. Here dim�m D 10, and � D 9, which suggests that should be surjective and that its fibres should all have dimension � 1. We shall see that thisis correct.

A quadric is said to be nondegenerate if it is defined by an irreducible polynomial ofdegree 2. After a change of variables, any nondegenerate quadric will be defined by anequation

XW D YZ:

178 10. REGULAR MAPS AND THEIR FIBRES

This is just the image of the Segre mapping (see 6.23)

.a0 W a1/, .b0 W b1/ 7! .a0b0 W a0b1 W a1b0 W a1b1/ W P1�P1! P3:

There are two obvious families of lines on P1�P1, namely, the horizontal family and thevertical family; each is parametrized by P1, and so is called a pencil of lines. They map totwo families of lines on the quadric:�

t0X D t1Z

t0Y D t1Wand

�t0X D t1Y

t0Z D t1W:

Since a degenerate quadric is a surface or a union of two surfaces, we see that every quadricsurface contains a line, that is, that W�2! P9 is surjective. Thus (10.9) tells us that all thefibres have dimension� 1, and the set where the dimension is> 1 is a proper closed subset.In fact the dimension of the fibre is > 1 exactly on the set of reducible F ’s, which we knowto be closed (this was a homework problem in the original course).

It follows from the above discussion that if F is nondegenerate, then �1.F / is iso-morphic to the disjoint union of two lines, �1.F /� P1[P1. Classically, one defines aregulus to be a nondegenerate quadric surface together with a choice of a pencil of lines.One can show that the set of reguli is, in a natural way, an algebraic variety R, and that,over the set of nondegenerate quadrics, factors into the composite of two regular maps:

�2� �1.S/ D pairs, .F;L/ with L on F I#

R D set of reguli;#

P9�S D set of nondegenerate quadrics.

The fibres of the top map are connected, and of dimension 1 (they are all isomorphic toP1/, and the second map is finite and two-to-one. Factorizations of this type occur quitegenerally (see the Stein factorization theorem (10.30) below).

We now look at the case mD 3. Here dim�3 D 19; � D 19 W we have a map

W�3! P19:

THEOREM 10.27. The set of cubic surfaces containing exactly 27 lines corresponds to anopen subset of P19; the remaining surfaces either contain an infinite number of lines or anonzero finite number � 27.

EXAMPLE 10.28. (a) Consider the Fermat surface

X30 CX31 CX

32 CX

33 D 0:

Let � be a primitive cube root of one. There are the following lines on the surface, 0 �i;j � 2: �

X0C �iX1 D 0

X2C �jX3 D 0

�X0C �

iX2 D 0

X1C �jX3 D 0

�X0C �

iX3 D 0

X1C �jX2 D 0

There are three sets, each with nine lines, for a total of 27 lines.

Lines on surfaces 179

(b) Consider the surfaceX1X2X3 DX

30 :

In this case, there are exactly three lines. To see this, look first in the affine space whereX0 ¤ 0—here we can take the equation to be X1X2X3 D 1. A line in A3 can be written inparametric form Xi D ai t C bi , but a direct inspection shows that no such line lies on thesurface. Now look where X0 D 0, that is, in the plane at infinity. The intersection of thesurface with this plane is given by X1X2X3 D 0 (homogeneous coordinates), which is theunion of three lines, namely,

X1 D 0; X2 D 0; X3 D 0:

Therefore, the surface contains exactly three lines.(c) Consider the surface

X31 CX32 D 0:

Here there is a pencil of lines: �t0X1 D t1X0t0X2 D�t1X0:

(In the affine space where X0 ¤ 0, the equation is X3CY 3 D 0, which contains the lineX D t , Y D�t , all t:/

We now discuss the proof of Theorem 10.27). If W�3! P19 were not surjective, then .�3/ would be a proper closed subvariety of P19, and the nonempty fibres would all havedimension � 1 (by 10.9), which contradicts two of the above examples. Therefore the mapis surjective1, and there is an open subset U of P19 where the fibres have dimension 0;outside U , the fibres have dimension > 0.

Given that every cubic surface has at least one line, it is not hard to show that there isan open subset U 0 where the cubics have exactly 27 lines (see Reid, 1988, pp106–110); infact, U 0 can be taken to be the set of nonsingular cubics. According to (8.23), the restrictionof to �1.U / is finite, and so we can apply (10.12) to see that all cubics in U �U 0 havefewer than 27 lines.

REMARK 10.29. The twenty-seven lines on a cubic surface were discovered in 1849 bySalmon and Cayley, and have been much studied—see A. Henderson, The Twenty-SevenLines Upon the Cubic Surface, Cambridge University Press, 1911. For example, it is knownthat the group of permutations of the set of 27 lines preserving intersections (that is, suchthat L\L0 ¤ ; ” �.L/\ �.L0/ ¤ ;/ is isomorphic to the Weyl group of the rootsystem of a simple Lie algebra of type E6, and hence has 25920 elements.

It is known that there is a set of 6 skew lines on a nonsingular cubic surface V . Let Land L0 be two skew lines. Then “in general” a line joining a point on L to a point on L0 willmeet the surface in exactly one further point. In this way one obtains an invertible regularmap from an open subset of P1 �P1 to an open subset of V , and hence V is birationallyequivalent to P2.

1According to Miles Reid (1988, p126) every adult algebraic geometer knows the proof that every cubiccontains a line.

180 10. REGULAR MAPS AND THEIR FIBRES

Stein factorization

The following important theorem shows that the fibres of a proper map are disconnectedonly because the fibres of finite maps are disconnected.

THEOREM 10.30. Let 'WW ! V be a proper morphism of varieties. It is possible to factor' into W

'1!W 0

'2! V with '1 proper with connected fibres and '2 finite.

PROOF. This is usually proved at the same time as Zariski’s main theorem (ifW and V areirreducible, and V is affine, then W 0 is the affine variety with kŒW 0� the integral closure ofkŒV � in k.W /). 2

Exercises

10-1. Let G be a connected algebraic group, and consider an action of G on a variety V ,i.e., a regular mapG�V ! V such that .gg0/vD g.g0v/ for all g;g0 2G and v 2 V . Showthat each orbit O DGv of G is nonsingular and open in its closure NO , and that NOrO is aunion of orbits of strictly lower dimension. Deduce that there is at least one closed orbit.

10-2. Let G D GL2 D V , and let G act on V by conjugation. According to the theory ofJordan canonical forms, the orbits are of three types:

(a) Characteristic polynomial X2CaXCb; distinct roots.(b) Characteristic polynomial X2C aX C b; minimal polynomial the same; repeated

roots.(c) Characteristic polynomial X2CaXCb D .X �˛/2; minimal polynomial X �˛.

For each type, find the dimension of the orbit, the equations defining it (as a subvariety ofV ), the closure of the orbit, and which other orbits are contained in the closure.

(You may assume, if you wish, that the characteristic is zero. Also, you may assume thefollowing (fairly difficult) result: for any closed subgroupH of an algebraic groupG,G=Hhas a natural structure of an algebraic variety with the following properties: G! G=H isregular, and a map G=H ! V is regular if the composite G ! G=H ! V is regular;dimG=H D dimG�dimH .)

[The enthusiasts may wish to carry out the analysis for GLn.]

10-3. Find 3d2 lines on the Fermat projective surface

Xd0 CXd1 CX

d2 CX

d3 D 0; d � 3; .p;d/D 1; p the characteristic.

10-4. (a) Let 'WW ! V be a quasi-finite dominant regular map of irreducible varieties.Show that there are open subsetsU 0 andU ofW and V such that '.U 0/�U and 'WU 0!U

is finite.(b) Let G be an algebraic group acting transitively on irreducible varieties W and V ,

and let 'WW ! V be G-equivariant regular map satisfying the hypotheses in (a). Then ' isfinite, and hence proper.

CHAPTER 11Algebraic spaces; geometry over an

arbitrary field

In this chapter, we explain how to extend the theory of the preceding chapters to a nonalge-braically closed base field. One major difference is that we need to consider ringed spacesin which the sheaf of rings is no longer a sheaf of functions on the base space. Once weallow that degree of extra generality, it is natural to allow the rings to have nilpotents. Inthis way we obtain the notion of an algebraic space, which even over an algebraically closedfield is more general than that of an algebraic variety.

Throughout this chapter, k is a field and kal is an algebraic closure of k.

Preliminaries

Sheaves

A presheaf F on a topological space V is a map assigning to each open subset U of V aset F.U / and to each inclusion U 0 � U a “restriction” map

a 7! ajU 0WF.U /! F.U 0/I

when U D U 0 the restriction map is required to be the identity map, and if

U 00 � U 0 � U;

then the composite of the restriction maps

F.U /! F.U 0/! F.U 00/

is required to be the restriction map F.U /! F.U 00/. In other words, a presheaf is acontravariant functor to the category of sets from the category whose objects are the opensubsets of V and whose morphisms are the inclusions. A homomorphism of presheaves˛WF ! F 0 is a family of maps

˛.U /WF.U /! F 0.U /

commuting with the restriction maps, i.e., a morphism of functors.

181

182 11. ALGEBRAIC SPACES; GEOMETRY OVER AN ARBITRARY FIELD

A presheaf F is a sheaf if for every open covering fUig of an open subset U of Vand family of elements ai 2 F.Ui / agreeing on overlaps (that is, such that ai jUi \Uj Daj jUi \Uj for all i;j ), there is a unique element a 2 F.U / such that ai D ajUi for all i .A homomorphism of sheaves on V is a homomorphism of presheaves.

If the sets F.U / are abelian groups and the restriction maps are homomorphisms, thenthe sheaf is a sheaf of abelian groups. Similarly one defines a sheaf of rings, a sheaf ofk-algebras, and a sheaf of modules over a sheaf of rings.

For v 2 V , the stalk of a sheaf F (or presheaf) at v is

Fv D lim�!

F.U / (limit over open neighbourhoods of v/:

In other words, it is the set of equivalence classes of pairs .U;s/ with U an open neighbour-hood of v and s 2 F.U /; two pairs .U;s/ and .U 0; s0/ are equivalent if sjU 00 D s0jU 00 forsome open neighbourhood U 00 of v contained in U \U 0.

A ringed space is a pair .V;O/ consisting of topological space V together with a sheafof rings. If the stalk Ov of O at v is a local ring for all v 2 V , then .V;O/ is called a locallyringed space.

A morphism .V;O/! .V 0;O 0/ of ringed spaces is a pair .'; / with ' a continuousmap V ! V 0 and a family of maps

.U 0/WO0.U 0/!O.'�1.U 0//; U 0 open in V 0,

commuting with the restriction maps. Such a pair defines homomorphism of rings vWO0'.v/!Ov for all v 2 V . A morphism of locally ringed spaces is a morphism of ringed space suchthat v is a local homomorphism for all v.

In the remainder of this chapter, a ringed space will be a topological space V togetherwith a sheaf of k-algebras, and morphisms of ringed spaces will be required to preservethe k-algebra structures.

Extending scalars (extending the base field)

Nilpotents

Recall that a ring A is reduced if it has no nilpotents. The ring A may be reduced withoutA˝k k

al being reduced. Consider for example the algebra A D kŒX;Y �=.XpCY pC a/where p D char.k/ and a is not a pth-power in k. Then A is reduced (even an integraldomain) because XpCY pCa is irreducible in kŒX;Y �, but

A˝k kal' kalŒX;Y �=.XpCY pCa/

D kalŒX;Y �=..XCY C˛/p/; ˛p D a;

which is not reduced because it contains the nonzero element xCyC˛ whose pth poweris zero.

In this subsection, we show that problems of this kind arise only because of insepara-bility. In particular, they don’t occur if k is perfect.

Now assume k has characteristic p ¤ 0, and let ˝ be some (large) field containing kal.Let

k1p D f˛ 2 kal

j ˛p 2 kg:

It is a subfield of kal, and k1p D k if and only if k is perfect.

Preliminaries 183

DEFINITION 11.1. Subfields K;K 0 of ˝ containing k are said to be linearly disjoint overk if the map K˝kK 0!˝ is injective.

Equivalent conditions:

˘ if e1; : : : ; em 2 K are linearly independent over k and e01; : : : ; e0m0 2 K

0 are linearlyindependent over k, then the elements e1e01; e1e

02; : : : ; eme

0m0 of ˝ are linearly inde-

pendent over k;˘ if e1; : : : ; em 2K are linearly independent over k, then they are also linearly indepen-

dent over K 0.

(*) The following statements are easy to prove.

(a) Every purely transcendental extension of k is linearly disjoint from every algebraicextension of k.

(b) Every separable algebraic extension of k is linearly disjoint from every purely insep-arable algebraic extension of k.

(c) Let K � k and L � E � k be subfields of ˝. Then K and L are linearly disjointover k if and only if K and E are linearly disjoint over k and KE and L are linearlydisjoint over k.

LEMMA 11.2. Let K D k.x1; : : : ;xdC1/ � ˝ with x1; : : : ;xd algebraically independentoverF , and let f 2 kŒX1; : : : ;XdC1� be an irreducible polynomial such that f .x1; : : : ;xdC1/D0. If K is linearly disjoint from k

1p , then f … kŒXp1 ; : : : ;X

p

dC1�.

PROOF. Suppose otherwise, say, f D g.Xp1 ; : : : ;Xp

dC1/. Let M1; : : : ;Mr be the monomi-

als inX1; : : : ;XdC1 that actually occur in g.X1; : : : ;XdC1/, and letmi DMi .x1; : : : ;xdC1/.Then m1; : : : ;mr are linearly independent over k (because each has degree less than that off ). However, mp1 ; : : : ;m

pr are linearly dependent over k, because g.xp1 ; : : : ;x

p

dC1/ D 0.

But Xaim

pi D 0 .ai 2 k/ H)

Xa1p

i mi D 0 .a1p

i 2 k1p /

and we have a contradiction. 2

A separating transcendence basis forK � k is a transcendence basis fx1; : : : ;xd g suchthatK is separable over k.x1; : : : ;xd /. The next proposition improves Theorem 8.21 of FT.

PROPOSITION 11.3. Let K be a finitely generated field extension of k, and let ˝ be analgebraically closed field containing Kal. The following statements are equivalent:

(a) K=k admits a separating transcendence basis;(b) for any purely inseparable extension L of k in K, the fields K and L are linearly

disjoint over k;(c) the fields K and k

1p are linearly disjoint over k.

PROOF. (a))(b). This follows easily from (*).(b))(c). Trivial.(c))(a). Let K D k.x1; : : : ;xn/, and let d be the transcendence degree of K=k. Af-

ter renumbering, we may suppose that x1; : : : ;xd are algebraically independent (FT 8.12).

184 11. ALGEBRAIC SPACES; GEOMETRY OVER AN ARBITRARY FIELD

We proceed by induction on n. If n D d there is nothing to prove, and so we may as-sume that n � d C1. Then f .x1; : : : ;xdC1/D 0 for some nonzero irreducible polynomialf .X1; : : : ;XdC1/ with coefficients in k. Not all @f=@Xi are zero, for otherwise f wouldbe a polynomial in Xp1 ; : : : ;X

p

dC1, which contradicts the lemma. After renumbering again,

we may suppose that @f=@XdC1 ¤ 0, and so fx1; : : : ;xd g is a separating transcendencebasis for k.x1; : : : ;xdC1/ over k, which proves the proposition when n D d C 1. In thegeneral case, k.x1; : : : ;xdC1;xdC2/ is algebraic over k.x1; : : : ;xd / and xdC1 is separableover k.x1; : : : ;xd /, and so, by the primitive element theorem (FT 5.1) there is an elementy such that k.x1; : : : ;xdC2/D k.x1; : : : ;xd ;y/. Thus K is generated by the n�1 elementsx1; : : :xd ;y;xdC3; : : : ;xn, and we apply induction. 2

A finitely generated field extension K � k is said to be regular if it satisfies the equiv-alent conditions of the proposition.

PROPOSITION 11.4. Let A be a reduced finitely generated k-algebra. The following state-ments are equivalent:

(a) k1p ˝k A is reduced;

(b) kal˝k A is reduced;(c) K˝k A is reduced for all fields K � k.

When A is an integral domain, they are also equivalent to A and k1p being linearly disjoint

over k.

PROOF. The implications cH)bH)a are obvious, and so we only have to prove a H)c.After localizing A at a minimal prime, we may suppose that it is a field. Let e1; : : : ; en beelements of A linearly independent over k. If they become linearly dependent over k

1p ,

then ep1 ; : : : ; epn are linearly dependent over k, say,

Paie

pi D 0, ai 2 k. Now

Pa1p

i ˝ ei is

a nonzero element of k1p ˝k A, but�P

a1p

i ˝ ei

�pDPai ˝ e

pi D

P1˝aie

pi D 1˝

Paie

pi D 0:

This shows that A and k1p are linearly disjoint over k, and so A has a separating transcen-

dence basis over k. From this it follows that K˝k A is reduced for all fields K � k. 2

Idempotents

Even when A is an integral domain and A˝k kal is reduced, the latter need not be anintegral domain. Suppose, for example, that A is a finite separable field extension of k.Then A� kŒX�=.f .X// for some irreducible separable polynomial f .X/, and so

A˝k kal� kalŒX�=.f .X//D kal=.

Q.X �ai //'

Qkal=.X �ai /

(by the Chinese remainder theorem). This shows that if A contains a finite separable fieldextension of k, then A˝k kal can’t be an integral domain. The next proposition provides aconverse.

Affine algebraic spaces 185

PROPOSITION 11.5. Let A be a finitely generated k-algebra, and assume that A is an inte-gral domain, and that A˝k kal is reduced. Then A˝k kal is an integral domain if and onlyif k is algebraically closed in A .i.e., if a 2 A is algebraic over k, then a 2 k/.

LEMMA 11.6. Let k be algebraically closed in an extension fieldK, and let a be an elementof Kal that is algebraic over k. Then K and kŒa� are linearly disjoint over k, and ŒKŒa� WK�D ŒkŒa� W k�.

PROOF. Let f .X/ be the minimum polynomial of a over k. Then f .X/ is irreducible overK, because the coefficients of any factor of f .X/ in KŒX� are algebraic over k, and hencelie in k. It follows that the map

K˝k kŒa�!KŒa�

is an isomorphism, because both rings are isomorphic to KŒX�=.f .X//. 2

PROOF (OF THE PROPOSITION) Let K be the field of fractions of A — it suffices to showthat K is linearly disjoint from L where L is any finite algebraic extension of k in Kal

(because then K˝k L'KL, which is an integral domain). If L is separable over k, thenit can be generated by a single element, and so this follows from the lemma. In the generalcase, we let E be the largest subfield of L separable over k. From (*)(c), we see that itsuffices to show that KE and L are linearly disjoint over E. From (11.4), we see that Kand k1=p are linearly disjoint over k, and so K is a regular extension of k (see 11.3). Itfollows easily that KE is a regular extension of E, and KE is linearly disjoint from L by(*)(b). 2

After these preliminaries, it is possible rewrite all of the preceding sections with k notnecessarily algebraically closed. I indicate briefly how this is done.

Affine algebraic spaces

For a finitely generated k-algebra A, we define spm.A/ to be the set of maximal ideals inA endowed with the topology having as basis the sets D.f /, D.f /D fm j f …mg. Thereis a unique sheaf of k-algebras O on spm.A/ such that � .D.f /;O//D Af for all f 2 A(recall that Af is the ring obtained from A by inverting f /, and we denote the resultingringed space by Spm.A/. The stalk at m 2 V is lim

�!fAf ' Am.

Let m be a maximal ideal of A. Then k.m/ defD A=m is field that is finitely generated as

a k-algebra, and is therefore of finite degree over k (Zariski’s lemma, 2.7).The sections of O are no longer functions on V D spmA. For m 2 spm.A/ and f 2 A

we set f .m/ equal to the image of f in k.m/. It does make sense to speak of the zero setof f in V , and D.f /D fm j f .m/¤ 0g. For f;g 2 A,

f .m/D g.m/ for all m 2 A ” f �g is nilpotent.

When k is algebraically closed and A is an affine k-algebra, k.m/' k and we recover thedefinition of SpmA in �3.

186 11. ALGEBRAIC SPACES; GEOMETRY OVER AN ARBITRARY FIELD

An affine algebraic space1 over k is a ringed space .V;OV / such that

˘ � .V;OV / is a finitely generated k-algebra,˘ for eachP 2V , I.P / def

Dff 2� .V;OV / jf .P /D 0g is a maximal ideal in � .V;OV /,and

˘ the map P 7! I.P /WV ! Spm.� .V;OV // is an isomorphism of ringed spaces.

For an affine algebraic space, we sometimes denote � .V;OV / by kŒV �. A morphism ofalgebraic spaces over k is a morphism of ringed spaces — it is automatically a morphism oflocally ringed spaces. An affine algebraic space .V;OV / is reduced if � .V;OV / is reduced.

Let ˛WA! B be a homomorphism of finitely generated k-algebras. For any maximalideal m of B , there is an injection of k-algebras A=˛�1.m/ ,! B=m. As B=m is a field offinite degree over k, this shows that ˛�1.m/ is a maximal ideal of A. Therefore ˛ definesa map spmB ! spmA, which one shows easily defines a morphism of affine algebraick-spaces

SpmB! Spm A;

and this gives a bijection

Homk-alg.A;B/' Homk.SpmB;SpmA/:

Therefore A 7! Spm.A/ is an equivalence of from the category of finitely generated k-algebras to that of affine algebraic spaces over k; its quasi-inverse is V 7! kŒV �

defD� .V;OV /.

Under this correspondence, reduced algebraic spaces correspond to reduced algebras.Let V be an affine algebraic space over k. For an ideal a in kŒV �,

spm.A=a/' V.a/ defD fP 2 V j f .P /D 0 for all f 2 ag:

We call V.a/ endowed with the ring structure provided by this isomorphism a closed alge-braic subspace of V . Thus, there is a one-to-one correspondence between the closed alge-braic subspaces of V and the ideals in kŒV �: Note that if rad.a/D rad.b/, then V.a/D V.b/as topological spaces (but not as algebraic spaces).

Let 'WSpm.B/! Spm.A/ be the map defined by a homomorphism ˛WA! B .

˘ The image of ' is dense if and only if the kernel of ˛ is nilpotent.˘ The map ' defines an isomorphism of Spm.B/ with a closed subvariety of Spm.A/

if and only if ˛ is surjective.

Affine algebraic varieties.

An affine k-algebra is a finitely generated k-algebra A such that A˝k kal is reduced. SinceA � A˝k k

al, A itself is then reduced. Proposition 11.4 has the following consequences:if A is an affine k-algebra, then A˝kK is reduced for all fields K containing k; when k isperfect, every reduced finitely generated k-algebra is affine.

Let A be a finitely generated k-algebra. The choice of a set fx1; :::;xng of generatorsfor A, determines isomorphisms

A! kŒx1; :::;xn�! kŒX1; :::;Xn�=.f1; :::;fm/;

1Not to be confused with the algebraic spaces of, for example, of J-P. Serre, Espaces Fibres Algebriques,1958, which are simply algebraic varieties in the sense of these notes, or with the algebraic spaces of M. Artin,Algebraic Spaces, 1969, which generalize (!) schemes.

Algebraic spaces; algebraic varieties. 187

andA˝k k

al! kalŒX1; :::;Xn�=.f1; :::;fm/:

Thus A is an affine algebra if the elements f1; :::;fm of kŒX1; :::;Xn� generate a radicalideal when regarded as elements of kalŒX1; :::;Xn�. From the above remarks, we see thatthis condition implies that they generate a radical ideal in kŒX1; :::;Xn�, and the converseimplication holds when k is perfect.

An affine algebraic space .V;OV / such that � .V;OV / is an affine k-algebra is called anaffine algebraic variety over k. Thus, a ringed space .V;OV / is an affine algebraic varietyif � .V;OV / is an affine k-algebra, I.P / is a maximal ideal in � .V;OV / for each P 2 V ,and P 7! I.P /WV ! spm.� .V;OV // is an isomorphism of ringed spaces.

Let

AD kŒX1; :::;Xm�=a;

B D kŒY1; :::;Yn�=b.

A homomorphism A! B is determined by a family of polynomials, Pi .Y1; :::;Yn/, i D1; :::;m; the homomorphism sends xi to Pi .y1; :::;yn/; in order to define a homomorphism,the Pi must be such that

F 2 aH) F.P1; :::;Pn/ 2 b;

two families P1; :::;Pm and Q1; :::;Qm determine the same map if and only if Pi � Qimod b for all i .

Let A be a finitely generated k-algebra, and let V D SpmA. For any field K � k,K˝k A is a finitely generated K-algebra, and hence we get a variety VK

defD Spm.K˝k

A/ over K. We say that VK has been obtained from V by extension of scalars or ex-tension of the base field. Note that if A D kŒX1; :::;Xn�=.f1; :::;fm/ then A˝k K DKŒX1; :::;Xn�=.f1; :::;fm/. The map V 7! VK is a functor from affine varieties over kto affine varieties over K.

Let V0D Spm.A0/ be an affine variety over k; and letW D V.b/ be a closed subvarietyof V def

D V0;kal . Then W arises by extension of scalars from a closed subvariety W0 of V0if and only if the ideal b of A0˝k kal is generated by elements of A0. Except when k isperfect, this is stronger than saying W is the zero set of a family of elements of A.

The definition of the affine space A.E/ attached to a vector space E works over anyfield.

Algebraic spaces; algebraic varieties.

An algebraic space over k is a ringed space .V;O/ for which there exists a finite covering.Ui / of V by open subsets such that .Ui ;OjUi / is an affine algebraic space over k for alli . A morphism of algebraic spaces (also called a regular map) over k is a morphismof locally ringed spaces of k-algebras. An algebraic space is separated if for all pairs ofmorphisms of k-spaces ˛;ˇWZ! V , the subset of Z on which ˛ and ˇ agree is closed.

Similarly, an algebraic prevariety over k is a ringed space .V;O/ for which there existsa finite covering .Ui / of V by open subsets such that .Ui ;OjUi / is an affine algebraicvariety over k for all i . A separated prevariety is called a variety.

With any algebraic space V over k we can associate a reduced algebraic space Vred suchthat

188 11. ALGEBRAIC SPACES; GEOMETRY OVER AN ARBITRARY FIELD

˘ Vred D V as a topological space,˘ for all open affines U � V , � .U;OVred/ is the quotient of � .U;OV / by its nilradical.

For example, if V D SpmkŒX1; : : : ;Xn�=a, then Vred D SpmkŒX1; : : : ;Xn�=rad.a/. Theidentity map Vred ! V is a regular map. Any closed subset of V can be given a uniquestructure of a reduced algebraic space.

Products.

If A and B are finitely generated k-algebras, then A˝k B is a finitely generated k-algebra,and Spm.A˝k B/ is the product of Spm.A/ and Spm.B/ in the category of algebraic k-spaces, i.e., it has the correct universal property. This definition of product extends in anatural way to all algebraic spaces.

The tensor product of two reduced k-algebras may fail to be reduced — consider forexample,

AD kŒX;Y �=.XpCY pCa/; B D kŒZ�=.Zp�a/; a … kp:

However, if A and B are affine k-algebras, then A˝kB is again an affine k-algebra. To seethis, note that (by definition), A˝k kal and B˝k kal are affine k-algebras, and therefore soalso is their tensor product over kal (4.15); but

.A˝k kal/˝kal .kal

˝k B/' ..A˝k kal/˝kal kal/˝k B ' .A˝k B/˝k k

al:

Thus, if V and W are algebraic (pre)varieties over k, then so also is their product.Just as in (4.24, 4.25), the diagonal � is locally closed in V �V , and it is closed if and

only if V is separated.

Extension of scalars (extension of the base field).

Let V be an algebraic space over k, and let K be a field containing k. There is a naturalway of defining an algebraic space VK over K, said to be obtained from V by extensionof scalars (or extension of the base field): if V is a union of open affines, V D

SUi , then

VK DSUi;K and the Ui;K are patched together the same way as the Ui . If K is algebraic

over k, there is a morphism .VK ;OVK /! .V;OV / that is universal: for any algebraic K-space W and morphism .W;OW /! .V;OV /, there exists a unique regular map W ! VKgiving a commutative diagram,

W VK K

V k:

9Š

The dimension of an algebraic space or variety doesn’t change under extension ofscalars.

When V is an algebraic space (or variety) over kal obtained from an algebraic space(or variety) V0 over k by extension of scalars, we sometimes call V0 a model for V over k.More precisely, a model of V over k is an algebraic space (or variety) V0 over k togetherwith an isomorphism 'WV ! V0;kal :

Algebraic spaces; algebraic varieties. 189

Of course, V need not have a model over k — for example, an elliptic curve

E W Y 2Z DX3CaXZ2CbZ3

over kal will have a model over k � kal if and only if its j -invariant j.E/ defD

1728.4a/3

�16.4a3C27b2/

lies in k. Moreover, when V has a model over k, it will usually have a large number ofthem, no two of which are isomorphic over k. Consider, for example, the quadric surfacein P3over Qal;

V WX2CY 2CZ2CW 2D 0:

The models over V over Q are defined by equations

aX2CbY 2C cZ2CdW 2D 0, a, b, c, d 2Q:

Classifying the models of V over Q is equivalent to classifying quadratic forms over Q in4 variables. This has been done, but it requires serious number theory. In particular, thereare infinitely many (see Chapter VIII of my notes on Class Field Theory).

Let V be an algebraic space over k. When k is perfect, Vred is an algebraic prevarietyover k, but not necessarily otherwise, i.e., .Vred/kal need not be reduced. This shows thatwhen k is not perfect, passage to the associated reduced algebraic space does not commutewith extension of the base field: we may have

.Vred/K ¤ .VK/red:

PROPOSITION 11.7. Let V be an algebraic space over a field k. Then V is an algebraicprevariety if and only if V

k1p

is reduced, in which case VK is reduced for all fields K � k.

PROOF. Apply 11.4. 2

Connectedness

A variety V over a field k is said to be geometrically connected if Vkal is connected, inwhich case, V˝ is connected for every field ˝ containing k.

We first examine zero-dimensional varieties. Over C, a zero-dimensional variety isnothing more than a finite set (finite disjoint union of copies of A0). Over R, a connectedzero-dimensional variety V is either geometrically connected (e.g., A0R) or geometricallynonconnected (e.g., V W X2C1; subvariety of A1), in which case V.C/ is a conjugate pairof complex points. Thus, one sees that to give a zero-dimensional variety over R is to givea finite set with an action of Gal.C=R/.

Similarly, a connected variety V over R may be geometrically connected, or it maydecompose over C into a pair of conjugate varieties. Consider, for example, the followingsubvarieties of A2:

L W Y C1 is a geometrically connected line over R;L0 W Y 2C1 is connected over R, but over C it decomposes as the pair of conjugate lines

Y D˙i .Note that R is algebraically closed2 in

RŒL�D RŒX;Y �=.Y C1/Š RŒX�

but not inRŒL0�D RŒX;Y �=.Y 2C1/Š

�RŒY �=.Y 2C1/

�ŒX�Š CŒX�:

2A field k is algebraically closed in a k-algebra A if every a 2 A algebraic over k lies in k.

190 11. ALGEBRAIC SPACES; GEOMETRY OVER AN ARBITRARY FIELD

PROPOSITION 11.8. An irreducible variety V over a field k is geometrically connected ifand only if k is algebraically closed in k.V /.

PROOF. This follows from the statement: let A be a finitely generated k-algebra such thatA is an integral domain and A˝k kal is reduced; then A˝kal is an integral domain if andonly if k is algebraically closed in A (11.5). 2

PROPOSITION 11.9. To give a zero-dimensional variety V over a field k is to give (equiv-alently)

(a) a finite set E plus, for each e 2E, a finite separable field extension Q.e/ of Q, or(b) a finite set S with a continuous3 (left) action of ˙ def

D Gal.ksep=k/.4

PROOF. Because each point of a variety is closed, the underlying topological space V ofa zero-dimensional variety .V;OV / is finite and discrete. For U an open affine in V , AD� .U;OV / is a finite affine k-algebra. In particular, it is reduced, and so the intersectionof its maximal ideals

TmD 0. The Chinese remainder theorem shows that A'

QA=m.

EachA=m is a finite field extension of k, and it is separable because otherwise .A=m/˝k kal

would not be reduced. This proves (a).The set S in (b) is V.ksep/ with the natural action of ˙ . We can recover .V;OV / from

S as follows: let V be the set ˙nS of orbits endowed with the discrete topology, and, fore D˙s 2˙nS , let k.e/D .ksep/˙s where ˙s is the stabilizer of s in ˙ ; then, for U � V ,� .U;OV /D

Qe2U k.e/. 2

PROPOSITION 11.10. Given a variety V over k, there exists a map f WV ! � from V to azero-dimensional variety � such that, for all e 2� , the fibre Ve is a geometrically connectedvariety over k.e/.

PROOF. Let � be the zero-dimensional variety whose underlying set is the set of connectedcomponents of V overQ and such that, for each eD Vi 2 � , k.e/ is the algebraic closure ofk in Q.Vi /. Apply (11.8) to see that the obvious map f WV ! � has the desired property.2

EXAMPLE 11.11. Let V be a connected variety over a k, and let k0 be the algebraic closureof k in k.V /. The map f WV ! Spmk realizes V as a geometrically connected variety overk. Conversely, for a geometrically connected variety f WV ! Spmk0 over a finite extensionof k, the composite of f with Spmk0! Spmk realizes V as a variety over k (connected,but not geometrically connected if k0 ¤ k).

EXAMPLE 11.12. Let f WV ! � be as in (11.10). When we regard � as a set with anaction of ˙ , then its points are in natural one-to-one correspondence with the connectedcomponents of Vksep and its ˙ -orbits are in natural one-to-one correspondence with theconnected components of V . Let e 2� and let V 0D f �1

ksep.e/— it is a connected componentof Vksep . Let˙e be the stabilizer of e; then V 0 arises from a geometrically connected varietyover k.e/ def

D .ksep/˙e .

ASIDE 11.13. Proposition 11.10 is a special case of Stein factorization (10.30).3This means that the action factors through the quotient of Gal.Qal=Q/ by an open subgroup (all open

subgroups of Gal.Qal=Q/ are of finite index, but not all subgroups of finite index are open).4The cognoscente will recognize this as Grothendieck’s way of expressing Galois theory over Q:

Algebraic spaces; algebraic varieties. 191

Fibred products

Fibred products exist in the category of algebraic spaces. For example, if R ! A andR! B are homomorphisms of finitely generated k-algebras, then A˝R B is a finitelygenerated k-algebras and

Spm.A/�Spm.R/ Spm.B/D Spm.A˝RB/:

For algebraic prevarieties, the situation is less satisfactory. Consider a variety S and tworegular maps V ! S andW ! S . Then .V �SW /red is the fibred product of V andW overS in the category of reduced algebraic k-spaces. When k is perfect, this is a variety, butnot necessarily otherwise. Even when the fibred product exists in the category of algebraicprevarieties, it is anomolous. The correct object is the fibred product in the category ofalgebraic spaces which, as we have observed, may no longer be an algebraic variety. Thisis one reason for introducing algebraic spaces.

Consider the fibred product:

A1 ���� A1�A1 fag

x 7!xp

??y ??yA1 ���� fag

In the category of algebraic varieties,A1�A1 fag is a single point if a is a pth power in k andis empty otherwise; in the category of algebraic spaces, A1�A1 fag D SpmkŒT �=.T p�a/,which can be thought of as a p-fold point (point with multiplicity p).

The points on an algebraic space

Let V be an algebraic space over k. A point of V with coordinates in k (or a point of Vrational over k, or a k-point of V ) is a morphism Spmk! V . For example, if V is affine,say V D Spm.A/, then a point of V with coordinates in k is a k-homomorphism A! k. IfA D kŒX1; :::;Xn�=.f1; :::;fm/, then to give a k-homomorphism A! k is the same as togive an n-tuple .a1; :::;an/ such that

fi .a1; :::;an/D 0, i D 1; :::;m:

In other words, if V is the affine algebraic space over k defined by the equations

fi .X1; : : : ;Xn/D 0; i D 1; : : : ;m

then a point of V with coordinates in k is a solution to this system of equations in k: Wewrite V.k/ for the points of V with coordinates in k.

We extend this notion to obtain the set of points V.R/ of a variety V with coordinatesin any k-algebra R. For example, when V D Spm.A/, we set

V.R/D Homk-alg.A;R/:

Again, ifAD kŒX1; :::;Xn�=.f1; :::;fm/;

thenV.R/D f.a1; :::;an/ 2R

nj fi .a1; :::;an/D 0; i D 1;2; :::;mg:

192 11. ALGEBRAIC SPACES; GEOMETRY OVER AN ARBITRARY FIELD

What is the relation between the elements of V and the elements of V.k/? Suppose Vis affine, say V D Spm.A/. Let v 2 V . Then v corresponds to a maximal ideal mv in A(actually, it is a maximal ideal), and we write k.v/ for the residue field Ov=mv. Then k.v/is a finite extension of k, and we call the degree of k.v/ over k the degree of v. Let K be afield algebraic over k: To give a point of V with coordinates inK is to give a homomorphismof k-algebras A! K: The kernel of such a homomorphism is a maximal ideal mv in A,and the homomorphisms A! k with kernel mv are in one-to-one correspondence withthe k-homomorphisms �.v/! K. In particular, we see that there is a natural one-to-onecorrespondence between the points of V with coordinates in k and the points v of V with�.v/D k, i.e., with the points v of V of degree 1. This statement holds also for nonaffinealgebraic varieties.

Now assume k to be perfect. The kal-rational points of V with image v 2 V are inone-to-one correspondence with the k-homomorphisms k.v/! kal — therefore, there areexactly deg.v/ of them, and they form a single orbit under the action of Gal.kal=k/. Thenatural map Vkal ! V realizes V (as a topological space) as the quotient of Vkal by theaction of Gal.kal=k/ — there is a one-to-one correspondence between the set of points ofV and the set of orbits for Gal.kal=k/ acting on V.kal/.

Local study

Let V D V.a/ � An, and let aD .f1; :::;fr/. Let d D dimV . The singular locus Vsing ofV is defined by the vanishing of the .n�d/� .n�d/ minors of the matrix

Jac.f1;f2; : : : ;fr/D

0BBBB@@f1@x1

@f1@x2

� � �@f1@xr

@f2@x1:::@fr@x1

@fr@xr

1CCCCA :

We say that v is nonsingular if some .n�d/� .n�d/ minor doesn’t vanish at v. We sayV is nonsingular if its singular locus is empty (i.e., Vsing is the empty variety or, equiva-lently, Vsing.k

al/ is empty) . Obviously V is nonsingular” Vkal is nonsingular; also theformation of Vsing commutes with extension of scalars. Therefore, if V is a variety, Vsing isa proper closed subvariety of V (Theorem 5.18).

THEOREM 11.14. Let V be an algebraic space over k:

(a) If P 2 V is nonsingular, then OP is regular.(b) If all points of V are nonsingular, then V is a nonsingular algebraic variety.

PROOF. (a) Similar arguments to those in Chapter 5 show that mP can be generated bydimV elements, and dimV is the Krull dimension of OP .

(b) It suffices to show that V is geometrically reduced, and so we may replace k withits algebraic closure. From (a), each local ring OP is regular, but regular local rings areintegral domains (CA 17.3).5 2

5One shows that if R is regular, then the associated graded ringL

mi=miC1 is a polynomial ring in dimRsymbols. Using this, one see that if xy D 0 in R, then one of x or y lies in

Tnm

n, which is zero by the Krullintersection theorem (1.8).

Projective varieties. 193

The converse to (a) of the theorem fails. For example, let k be a field of characteristicp ¤ 0;2, and let a be a nonzero element of k that is not a pth power. Then f .X;Y / DY 2CXp�a is irreducible, and remains irreducible over kal. Therefore,

AD kŒX;Y �=.f .X;Y //D kŒx;y�

is an affine k-algebra, and we let V be the curve SpmA. One checks that V is normal, andhence is regular by Atiyah and MacDonald 1969, 9.2. However,

@f

@XD 0;

@f

@YD 2Y;

and so .a1p ;0/ 2 Vsing.k

al/: the point P in V corresponding to the maximal ideal .y/ of Ais singular even though OP is regular.

The relation between “nonsingular” and “regular” is examined in detail in: Zariski,O., The Concept of a Simple Point of an Abstract Algebraic Variety, Transactions of theAmerican Mathematical Society, Vol. 62, No. 1. (Jul., 1947), pp. 1-52.

Separable points

Let V be an algebraic variety over k. Call a point P 2 V separable if k.P / is a separableextension of k.

PROPOSITION 11.15. The separable points are dense in V ; in particular, V.k/ is dense inV if k is separably closed.

PROOF. It suffices to prove this for each irreducible component of V , and we may re-place an irreducible component of V by any variety birationally equivalent with it (4.32).Therefore, it suffices to prove it for a hypersurface H in AdC1 defined by a polynomialf .X1; : : : ;XdC1/ that is separable when regarded as a polynomial in XdC1 with coeffi-cients in k.X1; : : : ;Xd / (4.34, 11.3). Then @f

@XdC1¤ 0 (as a polynomial inX1; : : : ;Xd ), and

on the nonempty open subset D. @f@XdC1

/ of Ad , f .a1; : : : ;ad ;XdC1/ will be a separablepolynomial. The points of H lying over points of U are separable. 2

Tangent cones

DEFINITION 11.16. The tangent cone at a pointP on an algebraic space V is Spm.gr.OP //.

When V is a variety over an algebraically closed field, this agrees with the definition inChapter 5, except that there we didn’t have the correct language to describe it — even inthat case, the tangent cone may be an algebraic space (not an algebraic variety).

Projective varieties.

Everything in this chapter holds, essentially unchanged, when k is allowed to be an arbitraryfield.

If Vkal is a projective variety, then so also is V . The idea of the proof is the following:to say that V is projective means that it has an ample divisor; but a divisorD on V is ampleif Dkal is ample on Vkal ; by assumption, there is a divisor D on Vkal that is ample; anymultiple of the sum of the Galois conjugates ofD will also be ample, but some such divisorwill arise from a divisor on V .

194 11. ALGEBRAIC SPACES; GEOMETRY OVER AN ARBITRARY FIELD

Complete varieties.

Everything in this chapter holds unchanged when k is allowed to be an arbitrary field.

Normal varieties; Finite maps.

As noted in (8.15), the Noether normalization theorem requires a different proof when thefield is finite. Also, as noted earlier in this chapter, one needs to be careful with the definitionof fibre. For example, one should define a regular map 'WV ! W to be quasifinite if thefibres of the map of sets V.kal/!W.kal/ are finite.

Otherwise, k can be allowed to be arbitrary.

Dimension theory

The dimension of a variety V over an arbitrary field k can be defined as in the case that kis algebraically closed. The dimension of V is unchanged by extension of the base field.Most of the results of this chapter hold for arbitrary base fields.

Regular maps and their fibres

Again, the results of this chapter hold for arbitrary fields provided one is careful with thenotion of a fibre.

Algebraic groups

We now define an algebraic group to be an algebraic space G together with regular maps

multWG�G; inverseWG!G; eWA0!G

making G.R/ into a group in the usual sense for all k-algebras R.

THEOREM 11.17. Let G be an algebraic group over k.

(a) If G is connected, then it is geometrically connected.(b) If G is geometrically reduced (i.e., a variety), then it is nonsingular.(c) If k is perfect and G is reduced, then it is geometrically reduced.(d) If k has characteristic zero, then G is geometrically reduced (hence nonsingular).

PROOF. (a) The existence of e shows that k is algebraically closed in k.G/. Therefore (a)follows from (11.8).

(b) It suffices to show that Gkal is nonsingular, but this we did in (5.20).(c) As k D k

1p , this follows from (11.7).

(d) See my notes, Algebraic Groups..., I, Theorem 6.31 (Cartier’s theorem). 2

Exercises

11-1. Show directly that, up to isomorphism, the curve X2CY 2 D 1 over C has exactlytwo models over R.

CHAPTER 12Divisors and Intersection Theory

In this chapter, k is an arbitrary field.

Divisors

Recall that a normal ring is an integral domain that is integrally closed in its field of frac-tions, and that a variety V is normal if Ov is a normal ring for all v 2 V . Equivalentcondition: for every open connected affine subset U of V , � .U;OV / is a normal ring.

REMARK 12.1. Let V be a projective variety, say, defined by a homogeneous ring R.When R is normal, V is said to be projectively normal. If V is projectively normal, then itis normal, but the converse statement is false.

Assume now that V is normal and irreducible.A prime divisor on V is an irreducible subvariety of V of codimension 1. A divisor on

V is an element of the free abelian group Div.V / generated by the prime divisors. Thus adivisor D can be written uniquely as a finite (formal) sum

D DX

niZi ; ni 2 Z; Zi a prime divisor on V:

The support jDj of D is the union of the Zi corresponding to nonzero ni ’s. A divisor issaid to be effective (or positive) if ni � 0 for all i . We get a partial ordering on the divisorsby defining D �D0 to mean D�D0 � 0:

Because V is normal, there is associated with every prime divisor Z on V a discretevaluation ring OZ . This can be defined, for example, by choosing an open affine subvarietyU of V such that U \Z ¤ ;; then U \Z is a maximal proper closed subset of U , and sothe ideal p corresponding to it is minimal among the nonzero ideals of R D � .U;O/I soRp is a normal ring with exactly one nonzero prime ideal pR — it is therefore a discretevaluation ring (Atiyah and MacDonald 9.2), which is defined to be OZ . More intrinsicallywe can define OZ to be the set of rational functions on V that are defined an open subset Uof V with U \Z ¤ ;.

Let ordZ be the valuation of k.V /� � Z with valuation ring OZ . The divisor of anonzero element f of k.V / is defined to be

div.f /DX

ordZ.f / �Z:

195

196 12. DIVISORS AND INTERSECTION THEORY

The sum is over all the prime divisors of V , but in fact ordZ.f / D 0 for all but finitelymany Z’s. In proving this, we can assume that V is affine (because it is a finite union ofaffines), say V D Spm.R/. Then k.V / is the field of fractions of R, and so we can writef D g=h with g;h 2 R, and div.f /D div.g/�div.h/. Therefore, we can assume f 2 R.The zero set of f , V.f / either is empty or is a finite union of prime divisors, V D

SZi

(see 9.2) and ordZ.f /D 0 unless Z is one of the Zi .The map

f 7! div.f /Wk.V /�! Div.V /

is a homomorphism. A divisor of the form div.f / is said to be principal, and two divisorsare said to be linearly equivalent, denoted D �D0, if they differ by a principal divisor.

When V is nonsingular, the Picard group Pic.V / of V is defined to be the group ofdivisors on V modulo principal divisors. (Later, we shall define Pic.V / for an arbitrary va-riety; when V is singular it will differ from the group of divisors modulo principal divisors,even when V is normal.)

EXAMPLE 12.2. Let C be a nonsingular affine curve corresponding to the affine k-algebraR. Because C is nonsingular, R is a Dedekind domain. A prime divisor on C can beidentified with a nonzero prime divisor in R, a divisor on C with a fractional ideal, andP ic.C / with the ideal class group of R.

Let U be an open subset of V , and let Z be a prime divisor of V . Then Z\U is eitherempty or is a prime divisor of U . We define the restriction of a divisor D D

PnZZ on V

to U to beDjU D

XZ\U¤;

nZ �Z\U:

When V is nonsingular, every divisor D is locally principal, i.e., every point P has anopen neighbourhood U such that the restriction of D to U is principal. It suffices to provethis for a prime divisor Z. If P is not in the support of D, we can take f D 1. The primedivisors passing through P are in one-to-one correspondence with the prime ideals p ofheight 1 in OP , i.e., the minimal nonzero prime ideals. Our assumption implies that OP isa regular local ring. It is a (fairly hard) theorem in commutative algebra that a regular localring is a unique factorization domain. It is a (fairly easy) theorem that a noetherian integraldomain is a unique factorization domain if every prime ideal of height 1 is principal (Nagata1962, 13.1). Thus p is principal in Op; and this implies that it is principal in � .U;OV / forsome open affine set U containing P (see also 9.13).

If DjU D div.f /, then we call f a local equation for D on U .

Intersection theory.

Fix a nonsingular variety V of dimension n over a field k, assumed to be perfect. LetW1 and W2 be irreducible closed subsets of V , and let Z be an irreducible component ofW1\W2. Then intersection theory attaches a multiplicity to Z. We shall only do this in aneasy case.

Intersection theory. 197

Divisors.

Let V be a nonsingular variety of dimension n, and let D1; : : : ;Dn be effective divisors onV . We say that D1; : : : ;Dn intersect properly at P 2 jD1j\ : : :\jDnj if P is an isolatedpoint of the intersection. In this case, we define

.D1 � : : : �Dn/P D dimkOP =.f1; : : : ;fn/

where fi is a local equation for Di near P . The hypothesis on P implies that this is finite.

EXAMPLE 12.3. In all the examples, the ambient variety is a surface.(a) Let Z1 be the affine plane curve Y 2 �X3, let Z2 be the curve Y D X2, and let

P D .0;0/. Then

.Z1 �Z2/P D dimkŒX;Y �.X;Y /=.Y �X2;Y 2�X3/D dimkŒX�=.X4�X3/D 3:

(b) If Z1 and Z2 are prime divisors, then .Z1 �Z2/P D 1 if and only if f1, f2 are localuniformizing parameters at P . Equivalently, .Z1 �Z2/P D 1 if and only if Z1 and Z2 aretransversal at P , that is, TZ1.P /\TZ2.P /D f0g.

(c) Let D1 be the x-axis, and let D2 be the cuspidal cubic Y 2�X3: For P D .0;0/,.D1 �D2/P D 3.

(d) In general, .Z1 �Z2/P is the “order of contact” of the curves Z1 and Z2.

We say thatD1; : : : ;Dn intersect properly if they do so at every point of intersection oftheir supports; equivalently, if jD1j\ : : :\jDnj is a finite set. We then define the intersec-tion number

.D1 � : : : �Dn/DX

P2jD1j\:::\jDnj

.D1 � : : : �Dn/P :

EXAMPLE 12.4. Let C be a curve. If D DPniPi , then the intersection number

.D/DX

ni Œk.Pi / W k�:

By definition, this is the degree of D.

Consider a regular map ˛WW ! V of connected nonsingular varieties, and let D be adivisor on V whose support does not contain the image ofW . There is then a unique divisor˛�D on W with the following property: if D has local equation f on the open subset Uof V , then ˛�D has local equation f ı˛ on ˛�1U . (Use 9.2 to see that this does define adivisor on W ; if the image of ˛ is disjoint from jDj, then ˛�D D 0.)

EXAMPLE 12.5. Let C be a curve on a surface V , and let ˛WC 0! C be the normalizationof C . For any divisor D on V ,

.C �D/D deg˛�D:

LEMMA 12.6 (ADDITIVITY). Let D1; : : : ;Dn;D be divisors on V . If .D1 � : : : �Dn/P and.D1 � : : : �D/P are both defined, then so also is .D1 � : : : �DnCD/P ; and

.D1 � : : : �DnCD/P D .D1 � : : : �Dn/P C .D1 � : : : �D/P :

198 12. DIVISORS AND INTERSECTION THEORY

PROOF. One writes some exact sequences. See Shafarevich 1994, IV.1.2. 2

Note that in intersection theory, unlike every other branch of mathematics, we add first,and then multiply.

Since every divisor is the difference of two effective divisors, Lemma 12.1 allows us toextend the definition of .D1 � : : : �Dn/ to all divisors intersecting properly (not just effectivedivisors).

LEMMA 12.7 (INVARIANCE UNDER LINEAR EQUIVALENCE). Assume V is complete. IfDn �D

0n, then

.D1 � : : : �Dn/D .D1 � : : : �D0n/:

PROOF. By additivity, it suffices to show that .D1 � : : : �Dn/D 0 ifDn is a principal divisor.For nD 1, this is just the statement that a function has as many poles as zeros (counted withmultiplicities). Suppose nD 2. By additivity, we may assume that D1 is a curve, and thenthe assertion follows from Example 12.5 because

D principal ) ˛�D principal.

The general case may be reduced to this last case (with some difficulty). See Shafare-vich 1994, IV.1.3. 2

LEMMA 12.8. For any n divisors D1; : : : ;Dn on an n-dimensional variety, there exists ndivisors D01; : : : ;D

0n intersect properly.

PROOF. See Shafarevich 1994, IV.1.4. 2

We can use the last two lemmas to define .D1 � : : : �Dn/ for any divisors on a completenonsingular variety V : choose D01; : : : ;D

0n as in the lemma, and set

.D1 � : : : �Dn/D .D01 � : : : �D

0n/:

EXAMPLE 12.9. Let C be a smooth complete curve over C, and let ˛WC !C be a regularmap. Then the Lefschetz trace formula states that

.� ��˛/D Tr.˛jH 0.C;Q/�Tr.˛jH 1.C;Q/CTr.˛jH 2.C;Q/:

In particular, we see that .� ��/ D 2� 2g, which may be negative, even though � is aneffective divisor.

Let ˛WW ! V be a finite map of irreducible varieties. Then k.W / is a finite extensionof k.V /, and the degree of this extension is called the degree of ˛. If k.W / is separableover k.V / and k is algebraically closed, then there is an open subset U of V such that˛�1.u/ consists exactly d D deg˛ points for all u 2 U . In fact, ˛�1.u/ always consists ofexactly deg˛ points if one counts multiplicities. Number theorists will recognize this as theformula

Peifi D d: Here the fi are 1 (if we take k to be algebraically closed), and ei is

the multiplicity of the i th point lying over the given point.A finite map ˛WW ! V is flat if every point P of V has an open neighbourhood U such

that � .˛�1U;OW / is a free � .U;OV /-module — it is then free of rank deg˛.

Intersection theory. 199

THEOREM 12.10. Let ˛WW ! V be a finite map between nonsingular varieties. For anydivisors D1; : : : ;Dn on V intersecting properly at a point P of V ,X

˛.Q/DP

.˛�D1 � : : : �˛�Dn/D deg˛ � .D1 � : : : �Dn/P :

PROOF. After replacing V by a sufficiently small open affine neighbourhood of P , we mayassume that ˛ corresponds to a map of rings A! B and that B is free of rank d D deg˛as an A-module. Moreover, we may assume that D1; : : : ;Dn are principal with equationsf1; : : : ;fn on V , and that P is the only point in jD1j \ : : :\ jDnj. Then mP is the onlyideal of A containing aD .f1; : : : ;fn/: Set S D ArmP ; then

S�1A=S�1aD S�1.A=a/D A=a

because A=a is already local. Hence

.D1 � : : : �Dn/P D dimA=.f1; : : : ;fn/:

Similarly,.˛�D1 � : : : �˛

�Dn/P D dimB=.f1 ı˛; : : : ;fn ı˛/:

But B is a free A-module of rank d , and

A=.f1; : : : ;fn/˝AB D B=.f1 ı˛; : : : ;fn ı˛/:

Therefore, as A-modules, and hence as k-vector spaces,

B=.f1 ı˛; : : : ;fn ı˛/� .A=.f1; : : : ;fn//d

which proves the formula. 2

EXAMPLE 12.11. Assume k is algebraically closed of characteristic p ¤ 0. Let ˛WA1!A1 be the Frobenius map c 7! cp. It corresponds to the map kŒX�! kŒX�, X 7! Xp, onrings. Let D be the divisor c. It has equation X � c on A1, and ˛�D has the equationXp� c D .X � /p. Thus ˛�D D p. /, and so

deg.˛�D/D p D p �deg.D/:

The general case.

Let V be a nonsingular connected variety. A cycle of codimension r on V is an element ofthe free abelian group C r.V / generated by the prime cycles of codimension r .

Let Z1 and Z2 be prime cycles on any nonsingular variety V , and let W be an irre-ducible component of Z1\Z2. Then

dim Z1Cdim Z2 � dim V Cdim W;

and we say Z1 and Z2 intersect properly at W if equality holds.Define OV;W to be the set of rational functions on V that are defined on some open

subset U of V with U \W ¤ ; — it is a local ring. Assume that Z1 and Z2 intersectproperly at W , and let p1 and p2 be the ideals in OV;W corresponding to Z1 and Z2 (so

200 12. DIVISORS AND INTERSECTION THEORY

pi D .f1;f2; :::;fr/ if the fj defineZi in some open subset of V meetingW /. The exampleof divisors on a surface suggests that we should set

.Z1 �Z2/W D dimkOV;W =.p1;p2/;

but examples show this is not a good definition. Note that

OV;W =.p1;p2/DOV;W =p1˝OV;W OV;W =p2:

It turns out that we also need to consider the higher Tor terms. Set

�O.O=p1;O=p2/DdimVXiD0

.�1/i dimk.TorOi .O=p1;O=p2//

where O D OV;W . It is an integer � 0, and D 0 if Z1 and Z2 do not intersect properly atW . When they do intersect properly, we define

.Z1 �Z2/W DmW; mD �O.O=p1;O=p2/:

When Z1 and Z2 are divisors on a surface, the higher Tor’s vanish, and so this definitionagrees with the previous one.

Now assume that V is projective. It is possible to define a notion of rational equivalencefor cycles of codimension r : letW be an irreducible subvariety of codimension r�1, and letf 2 k.W /�; then div.f / is a cycle of codimension r on V (sinceW may not be normal, thedefinition of div.f / requires care), and we let C r.V /0 be the subgroup of C r.V / generatedby such cycles as W ranges over all irreducible subvarieties of codimension r � 1 and franges over all elements of k.W /�. Two cycles are said to be rationally equivalent if theydiffer by an element of C r.V /0, and the quotient of C r.V / by C r.V /0 is called the Chowgroup CH r.V /. A discussion similar to that in the case of a surface leads to well-definedpairings

CH r.V /�CH s.V /! CH rCs.V /:

In general, we know very little about the Chow groups of varieties — for example, therehas been little success at finding algebraic cycles on varieties other than the obvious ones(divisors, intersections of divisors,...). However, there are many deep conjectures concern-ing them, due to Beilinson, Bloch, Murre, and others.

We can restate our definition of the degree of a variety in Pn as follows: a closedsubvariety V of Pn of dimension d has degree .V �H/ for any linear subspace of Pn ofcodimension d . (All linear subspaces of Pnof codimension r are rationally equivalent, andso .V �H/ is independent of the choice of H .)

REMARK 12.12. (Bezout’s theorem). A divisor D on Pn is linearly equivalent of ıH ,where ı is the degree of D and H is any hyperplane. Therefore

.D1 � � � � �Dn/D ı1 � � �ın

where ıj is the degree of Dj . For example, if C1 and C2 are curves in P2 defined by irre-ducible polynomials F1 and F2 of degrees ı1 and ı2 respectively, then C1 and C2 intersectin ı1ı2 points (counting multiplicities).

Exercises 201

References.

Fulton, W., Introduction to Intersection Theory in Algebraic Geometry, (AMS Publication;CBMS regional conference series #54.) This is a pleasant introduction.

Fulton, W., Intersection Theory. Springer, 1984. The ultimate source for everything todo with intersection theory.

Serre: Algebre Locale, Multiplicites, Springer Lecture Notes, 11, 1957/58 (third edition1975). This is where the definition in terms of Tor’s was first suggested.

Exercises

You may assume the characteristic is zero if you wish.

12-1. Let V D V.F / � Pn, where F is a homogeneous polynomial of degree ı withoutmultiple factors. Show that V has degree ı according to the definition in the notes.

12-2. LetC be a curve inA2 defined by an irreducible polynomial F.X;Y /, and assumeCpasses through the origin. Then F D FmCFmC1C�� � , m� 1, with Fm the homogeneouspart of F of degree m. Let � WW ! A2 be the blow-up of A2 at .0;0/, and let C 0 be theclosure of ��1.C r .0;0//. Let Z D ��1.0;0/. Write Fm D

QsiD1.aiX C biY /

ri , withthe .ai Wbi / being distinct points of P1, and show that C 0\Z consists of exactly s distinctpoints.

12-3. Find the intersection number of D1WY 2 D Xr and D2WY 2 D Xs , r > s > 2, at theorigin.

12-4. Find Pic.V / when V is the curve Y 2 DX3.

CHAPTER 13Coherent Sheaves; Invertible

Sheaves

In this chapter, k is an arbitrary field.

Coherent sheaves

Let V D SpmA be an affine variety over k, and let M be a finitely generated A-module.There is a unique sheaf of OV -modules M on V such that, for all f 2 A,

� .D.f /;M/DMf .D Af ˝AM/:

Such an OV -module M is said to be coherent. A homomorphism M ! N of A-modulesdefines a homomorphism M!N of OV -modules, andM 7!M is a fully faithful functorfrom the category of finitely generatedA-modules to the category of coherent OV -modules,with quasi-inverse M 7! � .V;M/.

Now consider a variety V . An OV -module M is said to be coherent if, for every openaffine subset U of V , MjU is coherent. It suffices to check this condition for the sets in anopen affine covering of V .

For example, OnV is a coherent OV -module. An OV -module M is said to be locallyfree of rank n if it is locally isomorphic to OnV , i.e., if every point P 2 V has an openneighbourhood such that MjU �OnV . A locally free OV -module of rank n is coherent.

Let v 2 V , and let M be a coherent OV -module. We define a �.v/-module M.v/ asfollows: after replacing V with an open neighbourhood of v, we can assume that it is affine;hence we may suppose that V D Spm.A/, that v corresponds to a maximal ideal m in A (sothat �.v/D A=m/, and M corresponds to the A-module M ; we then define

M.v/DM ˝A �.v/DM=mM:

It is a finitely generated vector space over �.v/. Don’t confuse M.v/ with the stalk Mv ofM which, with the above notations, is Mm DM ˝AAm. Thus

M.v/DMv=mMv D �.v/˝Am Mm:

Nakayama’s lemma (1.3) shows that

M.v/D 0)Mv D 0:

203

204 13. COHERENT SHEAVES; INVERTIBLE SHEAVES

The support of a coherent sheaf M is

Supp.M/D fv 2 V jM.v/¤ 0g D fv 2 V jMv ¤ 0g:

Suppose V is affine, and that M corresponds to the A-module M . Let a be the annihilatorof M :

aD ff 2 A j fM D 0g:

Then M=mM ¤ 0”m� a (for otherwise A=mA contains a nonzero element annihilat-ing M=mM ), and so

Supp.M/D V.a/:

Thus the support of a coherent module is a closed subset of V .Note that if M is locally free of rank n, then M.v/ is a vector space of dimension n for

all v. There is a converse of this.

PROPOSITION 13.1. If M is a coherent OV -module such that M.v/ has constant dimen-sion n for all v 2 V , then M is a locally free of rank n.

PROOF. We may assume that V is affine, and that M corresponds to the finitely generatedA-module M . Fix a maximal ideal m of A, and let x1; : : : ;xn be elements of M whoseimages in M=mM form a basis for it over �.v/. Consider the map

WAn!M; .a1; : : : ;an/ 7!X

aixi :

Its cokernel is a finitely generated A-module whose support does not contain v. Thereforethere is an element f 2 A, f … m, such that defines a surjection An

f! Mf . After

replacing A with Af we may assume that itself is surjective. For every maximal idealn of A, the map .A=n/n!M=nM is surjective, and hence (because of the condition onthe dimension of M.v/) bijective. Therefore, the kernel of is contained in nn (meaningn� � � � �n) for all maximal ideals n in A, and the next lemma shows that this implies thatthe kernel is zero. 2

LEMMA 13.2. Let A be an affine k-algebra. Then\mD 0 (intersection of all maximal ideals in A).

PROOF. When k is algebraically closed, we showed (4.13) that this follows from the strongNullstellensatz. In the general case, consider a maximal ideal m of A˝k kal. Then

A=.m\A/ ,! .A˝k kal/=mD kal;

and so A=m\A is an integral domain. Since it is finite-dimensional over k, it is a field,and so m\A is a maximal ideal in A. Thus if f 2 A is in all maximal ideals of A, then itsimage in A˝kal is in all maximal ideals of A, and so is zero. 2

For two coherent OV -modules M and N , there is a unique coherent OV -moduleM˝OV N such that

� .U;M˝OV N /D � .U;M/˝� .U;OV /� .U;N /

Invertible sheaves. 205

for all open affines U � V . The reader should be careful not to assume that this formulaholds for nonaffine open subsets U (see example 13.4 below). For a such a U , one writesU D

SUi with the Ui open affines, and defines � .U;M˝OV N / to be the kernel ofY

i

� .Ui ;M˝OV N /⇒Yi;j

� .Uij ;M˝OV N /:

Define Hom.M;N / to be the sheaf on V such that

� .U;Hom.M;N //DHomOU .M;N /

(homomorphisms of OU -modules) for all open U in V . It is easy to see that this is a sheaf.If the restrictions of M and N to some open affine U correspond to A-modules M and N ,then

� .U;Hom.M;N //D HomA.M;N /;

and so Hom.M;N / is again a coherent OV -module.

Invertible sheaves.

An invertible sheaf on V is a locally free OV -module L of rank 1. The tensor product oftwo invertible sheaves is again an invertible sheaf. In this way, we get a product structureon the set of isomorphism classes of invertible sheaves:

ŒL� � ŒL0� defD ŒL˝L0�:

The product structure is associative and commutative (because tensor products are associa-tive and commutative, up to isomorphism), and ŒOV � is an identity element. Define

L_ DHom.L;OV /:

Clearly, L_ is free of rank 1 over any open set where L is free of rank 1, and so L_ is againan invertible sheaf. Moreover, the canonical map

L_˝L!OV ; .f;x/ 7! f .x/

is an isomorphism (because it is an isomorphism over any open subset where L is free).Thus

ŒL_�ŒL�D ŒOV �:

For this reason, we often write L�1 for L_.From these remarks, we see that the set of isomorphism classes of invertible sheaves on

V is a group — it is called the Picard group, Pic.V /, of V .We say that an invertible sheaf L is trivial if it is isomorphic to OV — then L represents

the zero element in Pic.V /.

PROPOSITION 13.3. An invertible sheaf L on a complete variety V is trivial if and only ifboth it and its dual have nonzero global sections, i.e.,

� .V;L/¤ 0¤ � .V;L_/:

206 13. COHERENT SHEAVES; INVERTIBLE SHEAVES

PROOF. We may assume that V is irreducible. Note first that, for any OV -module M onany variety V , the map

Hom.OV ;M/! � .V;M/; ˛ 7! ˛.1/

is an isomorphism.Next recall that the only regular functions on a complete variety are the constant func-

tions (see 7.5 in the case that k is algebraically closed), i.e., � .V;OV / D k0 where k0 isthe algebraic closure of k in k.V /. Hence Hom.OV ;OV /D k0, and so a homomorphismOV !OV is either 0 or an isomorphism.

We now prove the proposition. The sections define nonzero homomorphisms

s1WOV ! L; s2WOV ! L_:

We can take the dual of the second homomorphism, and so obtain nonzero homomorphisms

OVs1! L

s_2!OV :

The composite is nonzero, and hence an isomorphism, which shows that s_2 is surjective,and this implies that it is an isomorphism (for any ring A, a surjective homomorphism ofA-modules A! A is bijective because 1 must map to a unit). 2

Invertible sheaves and divisors.

Now assume that V is nonsingular and irreducible. For a divisor D on V , the vector spaceL.D/ is defined to be

L.D/D ff 2 k.V /� j div.f /CD � 0g:

We make this definition local: define L.D/ to be the sheaf on V such that, for any open setU ,

� .U;L.D//D ff 2 k.V /� j div.f /CD � 0 on U g[f0g:

The condition “div.f /CD � 0 on U ” means that, ifDDPnZZ, then ordZ.f /CnZ � 0

for all Z with Z\U ¤ ;. Thus, � .U;L.D// is a � .U;OV /-module, and if U � U 0, then� .U 0;L.D// � � .U;L.D//: We define the restriction map to be this inclusion. In thisway, L.D/ becomes a sheaf of OV -modules.

Suppose D is principal on an open subset U , say DjU D div.g/, g 2 k.V /�. Then

� .U;L.D//D ff 2 k.V /� j div.fg/� 0 on U g[f0g:

Therefore,� .U;L.D//! � .U;OV /; f 7! fg;

is an isomorphism. These isomorphisms clearly commute with the restriction maps forU 0 � U , and so we obtain an isomorphism L.D/jU ! OU . Since every D is locallyprincipal, this shows that L.D/ is locally isomorphic to OV , i.e., that it is an invertiblesheaf. If D itself is principal, then L.D/ is trivial.

Next we note that the canonical map

L.D/˝L.D0/! L.DCD0/; f ˝g 7! fg

Invertible sheaves and divisors. 207

is an isomorphism on any open set whereD andD0are principal, and hence it is an isomor-phism globally. Therefore, we have a homomorphism

Div.V /! Pic.V /; D 7! ŒL.D/�;

which is zero on the principal divisors.

EXAMPLE 13.4. Let V be an elliptic curve, and let P be the point at infinity. LetD be thedivisor D D P . Then � .V;L.D// D k, the ring of constant functions, but � .V;L.2D//contains a nonconstant function x. Therefore,

� .V;L.2D//¤ � .V;L.D//˝� .V;L.D//;

— in other words, � .V;L.D/˝L.D//¤ � .V;L.D//˝� .V;L.D//.

PROPOSITION 13.5. For an irreducible nonsingular variety, the map D 7! ŒL.D/� definesan isomorphism

Div.V /=PrinDiv.V /! Pic.V /:

PROOF. (Injectivity). If s is an isomorphism OV ! L.D/, then g D s.1/ is an element ofk.V /� such that

(a) div.g/CD � 0 (on the whole of V );(b) if div.f /CD � 0 on U , that is, if f 2 � .U;L.D//, then f D h.gjU/ for some

h 2 � .U;OV /.

Statement (a) says thatD � div.�g/ (on the whole of V ). Suppose U is such thatDjUadmits a local equation f D 0. When we apply (b) to �f , then we see that div.�f / �div.g/ on U , so that DjU C div.g/ � 0. Since the U ’s cover V , together with (a) thisimplies that D D div.�g/:

(Surjectivity). Define

� .U;K/D�k.V /� if U is open and nonempty0 if U is empty.

Because V is irreducible, K becomes a sheaf with the obvious restriction maps. On anyopen subset U where LjU � OU , we have LjU ˝K � K. Since these open sets forma covering of V , V is irreducible, and the restriction maps are all the identity map, thisimplies that L˝K � K on the whole of V . Choose such an isomorphism, and identify Lwith a subsheaf of K. On any U where L�OU , LjU D gOU as a subsheaf of K, where gis the image of 1 2 � .U;OV /: Define D to be the divisor such that, on a U , g�1 is a localequation for D. 2

EXAMPLE 13.6. Suppose V is affine, say V D SpmA. We know that coherent OV -modules correspond to finitely generated A-modules, but what do the locally free sheavesof rank n correspond to? They correspond to finitely generated projective A-modules (CA10.4). The invertible sheaves correspond to finitely generated projective A-modules of rank1. Suppose for example that V is a curve, so that A is a Dedekind domain. This gives anew interpretation of the ideal class group: it is the group of isomorphism classes of finitelygenerated projective A-modules of rank one (i.e., such that M ˝AK is a vector space ofdimension one).

208 13. COHERENT SHEAVES; INVERTIBLE SHEAVES

This can be proved directly. First show that every (fractional) ideal is a projective A-module — it is obviously finitely generated of rank one; then show that two ideals areisomorphic as A-modules if and only if they differ by a principal divisor; finally, showthat every finitely generated projective A-module of rank 1 is isomorphic to a fractionalideal (by assumptionM ˝AK �K; when we choose an identificationM ˝AK DK, thenM �M ˝AK becomes identified with a fractional ideal). [Exercise: Prove the statementsin this last paragraph.]

REMARK 13.7. Quite a lot is known about Pic.V /, the group of divisors modulo linearequivalence, or of invertible sheaves up to isomorphism. For example, for any completenonsingular variety V , there is an abelian variety P canonically attached to V , called thePicard variety of V , and an exact sequence

0! P.k/! Pic.V /! NS.V /! 0

where NS.V / is a finitely generated group called the Neron-Severi group.Much less is known about algebraic cycles of codimension > 1, and about locally free

sheaves of rank > 1 (and the two don’t correspond exactly, although the Chern classes oflocally free sheaves are algebraic cycles).

Direct images and inverse images of coherent sheaves.

Consider a homomorphism A! B of rings. From an A-module M , we get an B-moduleB˝AM , which is finitely generated if M is finitely generated. Conversely, an B-moduleM can also be considered an A-module, but it usually won’t be finitely generated (unlessB is finitely generated as an A-module). Both these operations extend to maps of varieties.

Consider a regular map ˛WW ! V , and let F be a coherent sheaf of OV -modules.There is a unique coherent sheaf of OW -modules ˛�F with the following property: for anyopen affine subsets U 0 and U of W and V respectively such that ˛.U 0/ � U , ˛�F jU 0 isthe sheaf corresponding to the � .U 0;OW /-module � .U 0;OW /˝� .U;OV /� .U;F/.

Let F be a sheaf of OV -modules. For any open subset U of V , we define � .U;˛�F/D� .˛�1U;F/, regarded as a � .U;OV /-module via the map � .U;OV /! � .˛�1U;OW /.Then U 7! � .U;˛�F/ is a sheaf of OV -modules. In general, ˛�F will not be coherent,even when F is.

LEMMA 13.8. (a) For any regular maps U˛! V

ˇ!W and coherent OW -module F on

W , there is a canonical isomorphism

.ˇ˛/�F �! ˛�.ˇ�F/:

(b) For any regular map ˛WV !W , ˛� maps locally free sheaves of rank n to locally freesheaves of rank n (hence also invertible sheaves to invertible sheaves). It preservestensor products, and, for an invertible sheaf L, ˛�.L�1/' .˛�L/�1.

PROOF. (a) This follows from the fact that, given homomorphisms of rings A! B ! T ,T ˝B .B˝AM/D T ˝AM .

(b) This again follows from well-known facts about tensor products of rings. 2

See Kleiman.

Principal bundles 209

Principal bundles

To be added.

CHAPTER 14Differentials (Outline)

In this subsection, we sketch the theory of differentials. We allow k to be an arbitrary field.Let A be a k-algebra, and let M be an A-module. Recall (from �5) that a k-derivation

is a k-linear map DWA!M satisfying Leibniz’s rule:

D.fg/D f ıDgCg ıDf; all f;g 2 A:

A pair .˝1A=k

;d / comprising anA-module˝1A=k

and a k-derivation d WA!˝1A=k

is calledthe module of differential one-forms for A over kal if it has the following universal prop-erty: for any k-derivation DWA!M , there is a unique k-linear map ˛W˝1

A=k!M such

that D D ˛ ıd ,

A ˝1

M:

d

D 9Šk-linear

EXAMPLE 14.1. Let A D kŒX1; :::;Xn�; then ˝1A=k

is the free A-module with basis thesymbols dX1; :::;dXn, and

df DX @f

@XidXi :

EXAMPLE 14.2. Let AD kŒX1; :::;Xn�=a; then ˝1A=k

is the free A-module with basis thesymbols dX1; :::;dXn modulo the relations:

df D 0 for all f 2 a:

PROPOSITION 14.3. Let V be a variety. For each n � 0, there is a unique sheaf of OV -modules ˝n

V=kon V such that ˝n

V=k.U / D

Vn˝1A=k

whenever U D SpmA is an openaffine of V .

PROOF. Omitted. 2

The sheaf ˝nV=k

is called the sheaf of differential n-forms on V .

211

212 14. DIFFERENTIALS (OUTLINE)

EXAMPLE 14.4. Let E be the affine curve

Y 2 DX3CaXCb;

and assume X3C aX C b has no repeated roots (so that E is nonsingular). Write x andy for regular functions on E defined by X and Y . On the open set D.y/ where y ¤ 0,let !1 D dx=y, and on the open set D.3x2C a/, let !2 D 2dy=.3x2C a/. Since y2 Dx3CaxCb,

2ydy D .3x2Ca/dx:

and so !1 and !2 agree on D.y/\D.3x2Ca/. Since E DD.y/[D.3x2Ca/, we seethat there is a differential ! on E whose restrictions to D.y/ and D.3x2Ca/ are !1 and!2 respectively. It is an easy exercise in working with projective coordinates to show that! extends to a differential one-form on the whole projective curve

Y 2Z DX3CaXZ2CbZ3:

In fact, ˝1C=k

.C / is a one-dimensional vector space over k, with ! as basis. Note that ! D

dx=y D dx=.x3CaxC b/12 , which can’t be integrated in terms of elementary functions.

Its integral is called an elliptic integral (integrals of this form arise when one tries to findthe arc length of an ellipse). The study of elliptic integrals was one of the starting points forthe study of algebraic curves.

In general, if C is a complete nonsingular absolutely irreducible curve of genus g, then˝1C=k

.C / is a vector space of dimension g over k.

PROPOSITION 14.5. If V is nonsingular, then ˝1V=k

is a locally free sheaf of rank dim.V /

(that is, every point P of V has a neighbourhood U such that ˝1V=kjU � .OV jU/dim.V //.

PROOF. Omitted. 2

Let C be a complete nonsingular absolutely irreducible curve, and let ! be a nonzeroelement of ˝1

k.C/=k. We define the divisor .!/ of ! as follows: let P 2 C ; if t is a uni-

formizing parameter at P , then dt is a basis for˝1k.C/=k

as a k.C /-vector space, and so wecan write ! D fdt , f 2 k.V /�; define ordP .!/D ordP .f /, and .!/D

PordP .!/P .

Because k.C / has transcendence degree 1 over k, ˝1k.C/=k

is a k.C /-vector space of di-mension one, and so the divisor .!/ is independent of the choice of ! up to linear equiv-alence. By an abuse of language, one calls .!/ for any nonzero element of ˝1

k.C/=ka

canonical class K on C . For a divisor D on C , let `.D/D dimk.L.D//:

THEOREM 14.6 (RIEMANN-ROCH). Let C be a complete nonsingular absolutely irre-ducible curve over k:

(a) The degree of a canonical divisor is 2g�2.(b) For any divisor D on C ,

`.D/�`.K�D/D 1Cg�deg.D/:

213

More generally, if V is a smooth complete variety of dimension d , it is possible toassociate with the sheaf of differential d -forms on V a canonical linear equivalence classof divisors K. This divisor class determines a rational map to projective space, called thecanonical map.

ReferencesShafarevich, 1994, III.5.Mumford 1999, III.4.

CHAPTER 15Algebraic Varieties over the

Complex Numbers

This is only an outline.It is not hard to show that there is a unique way to endow all algebraic varieties over C

with a topology such that:

(a) on An D Cn it is just the usual complex topology;(b) on closed subsets of An it is the induced topology;(c) all morphisms of algebraic varieties are continuous;(d) it is finer than the Zariski topology.

We call this new topology the complex topology on V . Note that (a), (b), and (c) deter-mine the topology uniquely for affine algebraic varieties ((c) implies that an isomorphismof algebraic varieties will be a homeomorphism for the complex topology), and (d) thendetermines it for all varieties.

Of course, the complex topology is much finer than the Zariski topology — this can beseen even on A1. In view of this, the next two propositions are a little surprising.

PROPOSITION 15.1. If a nonsingular variety is connected for the Zariski topology, then itis connected for the complex topology.

Consider, for example, A1. Then, certainly, it is connected for both the Zariski topology(that for which the nonempty open subsets are those that omit only finitely many points)and the complex topology (that for which X is homeomorphic to R2). When we remove acircle from X , it becomes disconnected for the complex topology, but remains connectedfor the Zariski topology. This doesn’t contradict the proposition, because A1C with a circleremoved is not an algebraic variety.

Let X be a connected nonsingular (hence irreducible) curve. We prove that it is con-nected for the complex topology. Removing or adding a finite number of points to X willnot change whether it is connected for the complex topology, and so we can assume that Xis projective. SupposeX is the disjoint union of two nonempty open (hence closed) sets X1andX2. According to the Riemann-Roch theorem (14.6), there exists a nonconstant rationalfunction f on X having poles only in X1. Therefore, its restriction to X2 is holomorphic.Because X2 is compact, f is constant on each connected component of X2 (Cartan 19631,

1Cartan, H., Elementary Theory of Analytic Functions of One or Several Variables, Addison-Wesley, 1963.

215

216 15. ALGEBRAIC VARIETIES OVER THE COMPLEX NUMBERS

VI.4.5) say, f .z/D a on some infinite connected component. Then f .z/�a has infinitelymany zeros, which contradicts the fact that it is a rational function.

The general case can be proved by induction on the dimension (Shafarevich 1994,VII.2).

PROPOSITION 15.2. Let V be an algebraic variety over C, and let C be a constructiblesubset of V (in the Zariski topology); then the closure of C in the Zariski topology equalsits closure in the complex topology.

PROOF. Mumford 1999, I 10, Corollary 1, p60. 2

For example, if U is an open dense subset of a closed subset Z of V (for the Zariskitopology), then U is also dense in Z for the complex topology.

The next result helps explain why completeness is the analogue of compactness fortopological spaces.

PROPOSITION 15.3. Let V be an algebraic variety over C; then V is complete (as an alge-braic variety) if and only if it is compact for the complex topology.

PROOF. Mumford 1999, I 10, Theorem 2, p60. 2

In general, there are many more holomorphic (complex analytic) functions than thereare polynomial functions on a variety over C. For example, by using the exponential func-tion it is possible to construct many holomorphic functions on C that are not polynomialsin z, but all these functions have nasty singularities at the point at infinity on the Riemannsphere. In fact, the only meromorphic functions on the Riemann sphere are the rationalfunctions. This generalizes.

THEOREM 15.4. Let V be a complete nonsingular variety over C. Then V is, in a naturalway, a complex manifold, and the field of meromorphic functions on V (as a complexmanifold) is equal to the field of rational functions on V .

PROOF. Shafarevich 1994, VIII 3.1, Theorem 1. 2

This provides one way of constructing compact complex manifolds that are not alge-braic varieties: find such a manifold M of dimension n such that the transcendence degreeof the field of meromorphic functions on M is < n. For a torus Cg=� of dimension g > 1,this is typically the case. However, when the transcendence degree of the field of meromor-phic functions is equal to the dimension of manifold, thenM can be given the structure, notnecessarily of an algebraic variety, but of something more general, namely, that of an alge-braic space in the sense of Artin.2 Roughly speaking, an algebraic space is an object that islocally an affine algebraic variety, where locally means for the etale “topology” rather thanthe Zariski topology.3

One way to show that a complex manifold is algebraic is to embed it into projectivespace.

2Perhaps these should be called algebraic orbispaces (in analogy with manifolds and orbifolds).3Artin, Michael. Algebraic spaces. Whittemore Lectures given at Yale University, 1969. Yale Mathemati-

cal Monographs, 3. Yale University Press, New Haven, Conn.-London, 1971. vii+39 pp.Knutson, Donald. Algebraic spaces. Lecture Notes in Mathematics, Vol. 203. Springer-Verlag, Berlin-New

York, 1971. vi+261 pp.

217

THEOREM 15.5. Any closed analytic submanifold of Pn is algebraic.

PROOF. See Shafarevich 1994, VIII 3.1, in the nonsingular case. 2

COROLLARY 15.6. Any holomorphic map from one projective algebraic variety to a sec-ond projective algebraic variety is algebraic.

PROOF. Let 'WV !W be the map. Then the graph �' of ' is a closed subset of V �W , andhence is algebraic according to the theorem. Since ' is the composite of the isomorphismV ! �' with the projection �'!W , and both are algebraic, ' itself is algebraic. 2

Since, in general, it is hopeless to write down a set of equations for a variety (it is afairly hopeless task even for an abelian variety of dimension 3), the most powerful way wehave for constructing varieties is to first construct a complex manifold and then prove thatit has a natural structure as a algebraic variety. Sometimes one can then show that it hasa canonical model over some number field, and then it is possible to reduce the equationsdefining it modulo a prime of the number field, and obtain a variety in characteristic p.

For example, it is known that Cg=� (� a lattice in Cg/ has the structure of an algebraicvariety if and only if there is a skew-symmetric form on Cg having certain simple prop-erties relative to �. The variety is then an abelian variety, and all abelian varieties over Care of this form.

ReferencesMumford 1999, I.10.Shafarevich 1994, Book 3.

CHAPTER 16Descent Theory

Consider fields k �˝. A variety V over k defines a variety V˝ over˝ by extension of thebase field (�11). Descent theory attempts to answer the following question: what additionalstructure do you need to place on a variety over ˝, or regular map of varieties over ˝, toensure that it comes from k?

In this chapter, we shall make free use of the axiom of choice (usually in the form ofZorn’s lemma).

Models

Let ˝ � k be fields, and let V be a variety over ˝. Recall (p188) that a model of V over k(or a k-structure on V ) is a variety V0 over k together with an isomorphism 'WV ! V0˝ .Recall also that a variety over˝ need not have a model over k, and when it does it typicallywill have many nonisomorphic models.

Consider an affine variety. An embedding V ,!An˝ defines a model of V over k if I.V /

is generated by polynomials in kŒX1; : : : ;Xn�, because then I0defD I.V /\kŒX1; : : : ;Xn� is

a radical ideal, kŒX1; : : : ;Xn�=I0 is an affine k-algebra, and V.I0/ � Ank is a model of V .Moreover, every model .V0;'/ arises in this way, because every model of an affine varietyis affine. However, different embeddings in affine space will usually give rise to differentmodels. Similar remarks apply to projective varieties.

Note that the condition that I.V / be generated by polynomials in kŒX1; : : : ;Xn� isstronger than asking that V be the zero set of some polynomials in kŒX1; : : : ;Xn�. Forexample, let V D V.X CY C˛/ where ˛ is an element of ˝ such that ˛p 2 k but ˛ … k.Then V is the zero set of the polynomial XpCY pC˛p, which has coefficients in k, butI.V /D .XCY C˛/ is not generated by polynomials in kŒX;Y �.

Fixed fields

Let ˝ � k be fields, and let � be the group Aut.˝=k/ of automomorphisms of ˝ (as anabstract field) fixing the elements of k. Define the fixed field ˝� of � to be

fa 2˝ j �aD a for all � 2 � g:

PROPOSITION 16.1. The fixed field of � equals k in each of the following two cases:

219

220 16. DESCENT THEORY

(a) ˝ is a Galois extension of k (possibly infinite);(b) ˝ is a separably closed field and k is perfect.

PROOF. (a) See FT 7.8.(b) See FT 8.23. 2

REMARK 16.2. (a) The proof of Proposition 16.1 definitely requires the axiom of choice.For example, it is known that every measurable homomorphism of Lie groups is continuous,and so any measurable automorphism of C is equal to the identity map or to complex con-jugation. Therefore, without the axiom of choice, � def

D Aut.C=Q/ has only two elements,and C� D R.

(b) Suppose that˝ is algebraically closed and k is not perfect. Then k has characteristicp ¤ 0 and ˝ contains an element ˛ such that ˛ … k but ˛p D a 2 k. As ˛ is the uniqueroot of Xp�a, every automorphism of ˝ fixing k also fixes ˛, and so ˝� ¤ k.

The perfect closure of k in ˝ is the subfield

kp�1

D f˛ 2˝ j ˛pn

2 k for some ng

of ˝. Then kp�1

is purely inseparable over k, and when ˝ is algebraically closed, it isthe smallest perfect subfield of ˝ containing k.

COROLLARY 16.3. If ˝ is separably closed, then ˝� is a purely inseparable algebraicextension of k.

PROOF. When k has characteristic zero, ˝� D k, and there is nothing to prove. Thus,we may suppose that k has characteristic p ¤ 0. Choose an algebraic closure ˝al of ˝,and let kp

�1

be the perfect closure of k in ˝al. As ˝al is purely inseparable over ˝,every element � of � extends uniquely to an automorphism Q� of ˝al: let ˛ 2˝al and let˛p

n

2 ˝; then Q�.˛/ is the unique root of Xpn

� �.˛pn

/ in ˝. The action of � on ˝al

identifies it with Aut.˝al=kp�1

/. According to the proposition, .˝al/� D kp�1

, and so

kp�1

�˝� � k: 2

Descending subspaces of vector spaces

In this subsection, ˝ � k are fields such that k is the fixed field of � D Aut.˝=k/.Let V be a k-subspace of an ˝-vector space V.˝/ such that the map

c˝v 7! cvW˝˝k V ! V.˝/

is an isomorphism. Equivalent conditions: V is the k-span of an ˝-basis for V.˝/; everyk-basis for V is an ˝-basis for V.˝/. The group � acts on ˝˝k V through its action on˝:

�.Pci ˝vi /D

P�ci ˝vi ; � 2 �; ci 2˝; vi 2 V: (27)

Correspondingly, there is a unique action of � on V.˝/ fixing the elements of V and suchthat each � 2 � acts � -linearly:

�.cv/D �.c/�.v/ all � 2 � , c 2˝, v 2 V.˝/. (28)

Descending subspaces of vector spaces 221

LEMMA 16.4. The following conditions on a subspace W of V.˝/ are equivalent:

(a) W \V spans W ;(b) W \V contains an ˝-basis for W ;(c) the map ˝˝k .W \V /!W , c˝v 7! cv, is an isomorphism.

PROOF. (a) H) (b,c) A k-linearly independent subset of V is ˝-linearly independent inV.˝/. Therefore, if W \V spans W , then any k-basis .ei /i2I for W \V will be an ˝-basis for W . Moreover, .1˝ ei /i2I will be an ˝-basis for ˝˝k .W \V /, and since themap ˝˝k .W \V /!W sends 1˝ ei to ei , it is an isomorphism.

(c)H) (a), (b)H) (a). Obvious. 2

LEMMA 16.5. For any k-vector space V , V D V.˝/� .

PROOF. Let .ei /i2I be a k-basis for V . Then .1˝ ei /i2I is an ˝-basis for ˝˝k V , and� 2 � acts on v D

Pci ˝ei according to the rule (27). Thus, v is fixed by � if and only if

each ci is fixed by � and so lies in k. 2

LEMMA 16.6. Let V be a k-vector space, and let W be a subspace of V.˝/ stable underthe action of � . If W � D 0, then W D 0.

PROOF. Suppose W ¤ 0. As V contains an ˝-basis for V.˝/, every nonzero element wof W can be expressed in the form

w D c1e1C�� �C cnen; ci 2˝r f0g; ei 2 V; n� 1:

Choose w to be a nonzero element for which n takes its smallest value. After scaling, wemay suppose that c1 D 1. For � 2 � , the element

�w�w D .�c2� c2/e2C�� �C .�cn� cn/en

lies in W and has at most n�1 nonzero coefficients, and so is zero. Thus, w 2W � D f0g,which is a contradiction. 2

PROPOSITION 16.7. A subspaceW of V.˝/ is of the formW D˝W0 for some k-subspaceW0 of V if and only if it is stable under the action of � .

PROOF. Certainly, if W D ˝W0, then it is stable under � (and W D ˝.W \V /). Con-versely, assume that W is stable under � , and let W 0 be a complement to W \V in V , sothat

V D .W \V /˚W 0.

Then.W \˝W 0/� DW �

\�˝W 0

��D .W \V /\W 0 D 0,

and so, by (16.6),W \˝W 0 D 0. (29)

As W �˝.W \V / andV.˝/D˝.W \V /˚˝W 0,

this implies that W D˝.W \V /: 2

222 16. DESCENT THEORY

Descending subvarieties and morphisms

In this subsection, ˝ � k are fields such that k is the fixed field of � D Aut.˝=k/ and ˝is separably closed. Recall (11.15) that for any variety V over ˝, V.˝/ is Zariski dense inV . In particular, two regular maps V ! V 0 coincide if they agree on V.˝/.

For any variety V over k, � acts on V.˝/. For example, if V is embedded in An or Pnover k, then � acts on the coordinates of a point. If V D SpmA, then

V.˝/D Homk-algebra.A;˝/;

and � acts through its action on ˝.

PROPOSITION 16.8. Let V be a variety over k, and let W be a closed subvariety of V˝such that W.˝/ is stable under the action of � on V.˝/. Then there is a closed subvarietyW0 of V such that W DW0˝ .

PROOF. Suppose first that V is affine, and let I.W / � ˝ŒV˝ � be the ideal of regularfunctions zero on W . Recall that ˝ŒV˝ � D ˝ ˝k kŒV � (see �11). Because W.˝/ isstable under � , so also is I.W /, and Proposition 16.7 shows that I.W / is spanned byI0 D I.W /\kŒV �. Therefore, the zero set of I0 is a closed subvariety W0 of V with theproperty that W DW0˝ .

To deduce the general case, cover V with open affines V DSVi . ThenWi

defD Vi˝ \W

is stable under � , and so it arises from a closed subvariety Wi0 of Vi ; a similar statementholds for Wij

defD Wi \Wj . Define W0 to be the variety obtained by patching the varieties

Wi0 along the open subvarieties Wij0. 2

PROPOSITION 16.9. Let V and W be varieties over k, and let f WV˝ !W˝ be a regularmap. If f commutes with the actions of � on V.˝/ and W.˝/, then f arises from a(unique) regular map V !W over k.

PROOF. Apply Proposition 16.8 to the graph of f , �f � .V �W /˝ . 2

COROLLARY 16.10. A variety V over k is uniquely determined (up to a unique isomor-phism) by the variety V˝ together with action of � on V.˝/.

PROOF. More precisely, we have shown that the functor

V .V˝ ; action of � on V.˝// (30)

is fully faithful. 2

REMARK 16.11. In Theorems 16.42 and 16.43 below, we obtain sufficient conditions fora pair to lie in the essential image of the functor (30).

Galois descent of vector spaces 223

Galois descent of vector spaces

Let � be a group acting on a field ˝, and let k be a subfield of ˝� . By an action of � onan ˝-vector space V we mean a homomorphism � ! Autk.V / satisfying (28), i.e., suchthat each � 2 � acts � -linearly.

LEMMA 16.12. Let S be the standard Mn.k/-module (i.e., S D kn with Mn.k/ acting byleft multiplication). The functor V 7! S˝k V from k-vector spaces to leftMn.k/-modulesis an equivalence of categories.

PROOF. Let V and W be k-vector spaces. The choice of bases .ei /i2I and .fj /j2J for Vand W identifies Homk.V;W / with the set of matrices .aj i /.j;i/2J�I , aj i 2 k, such that,for a fixed i , all but finitely many aj i are zero. Because S is a simple Mn.k/-module andEndMn.k/.S/ D k, the set HomMn.k/.S ˝k V;S ˝kW / has the same description, and sothe functor V 7! S˝k V is fully faithful.

The functor V 7! S˝k V sends a vector space V with basis .ei /i2I to a direct sum ofcopies of S indexed by I . Therefore, to show that the functor is essentially surjective, wehave to prove that every left Mn.k/-module is a direct sum of copies of S .

We first prove this for Mn.k/ regarded as a left Mn.k/-module. For 1� i � n, let L.i/be the set of matrices in Mn.k/ whose entries are zero except for those in the i th column.Then L.i/ is a left ideal in Mn.k/, and L.i/ is isomorphic to S as an Mn.k/-module.Hence,

Mn.k/DMi

L.i/' Sn (as a left Mn.k/-module).

We now prove it for an arbitrary left Mn.k/-module M , which we may suppose to benonzero. The choice of a set of generators forM realizes it as a quotient of a sum of copiesof Mn.k/, and so M is a sum of copies of S . It remains to show that the sum can be madedirect. Let I be the set of submodules ofM isomorphic to S , and let� be the set of subsetsJ of I such that the sum N.J /

defDPN2J N is direct, i.e., such that for any N0 2 J and

finite subset J0 of J not containing N0, N0\PN2J0

N D 0. If J1 � J2 � : : : is a chainof sets in � , then

SJi 2 � , and so Zorn’s lemma implies that � has maximal elements.

For any maximal J , M D N.J / because otherwise, there exists an element S 0 of I notcontained in N.J /; because S 0 is simple, S 0\N.J /D 0, and it follows that J [fS 0g 2� ,contradicting the maximality of J . 2

ASIDE 16.13. Let A and B be rings (not necessarily commutative), and let S be A-B-bimodule (this means that A acts on S on the left, B acts on S on the right, and the actionscommute). When the functor M 7! S ˝B M WModB ! ModA is an equivalence of cat-egories, A and B are said to be Morita equivalent through S . In this terminology, thelemma says that Mn.k/ and k are Morita equivalent through S .

PROPOSITION 16.14. Let ˝ be a finite Galois extension of k with Galois group � . Thefunctor V ˝˝k V from k-vector spaces to ˝-vector spaces endowed with an action of� is an equivalence of categories.

PROOF. Let ˝Œ� � be the ˝-vector space with basis f� 2 � g, and make ˝Œ� � into a k-algebra by setting �P

�2� a����P

�2� b���DP�;� .a� ��b� /�� .

224 16. DESCENT THEORY

Then ˝Œ� � acts k-linearly on ˝ by the rule

.P�2� a��/c D

P�2� a� .�c/;

and Dedekind’s theorem on the independence of characters (FT 5.14) implies that the ho-momorphism

˝Œ� �! Endk.˝/

defined by this action is injective. By counting dimensions over k, one sees that it is an iso-morphism. Therefore, Lemma 16.12 shows that ˝Œ� � and k are Morita equivalent through˝, i.e., the functor V 7!˝˝k V from k-vector spaces to left ˝Œ� �-modules is an equiva-lence of categories. This is precisely the statement of the lemma. 2

When ˝ is an infinite Galois extension of k, we endow � with the Krull topology, andwe say that an action of � on an ˝-vector space V is continuous if every element of V isfixed by an open subgroup of � , i.e., if

V D[

�V � .union over the open subgroups � of � ).

For example, the action of � on ˝ is obviously continuous, and it follows that, for anyk-vector space V , the action of � on ˝˝k V is continuous.

PROPOSITION 16.15. Let ˝ be a Galois extension of k (possibly infinite) with Galoisgroup � . For any ˝-vector space V equipped with a continuous action of � , the mapP

ci ˝vi 7!Pcivi W˝˝k V

�! V

is an isomorphism.

PROOF. Suppose first that � is finite. Proposition 16.14 allows us to assume V D˝˝kWfor some k-subspace W of V . Then V � D .˝˝kW /� DW , and so the statement is true.

When � is infinite, the finite case shows that ˝˝k .V �/�=� ' V � for every opennormal subgroup� of � . Now pass to the direct limit over�, recalling that tensor productscommute with direct limits (CA 8.1). 2

Descent data

For a homomorphism of fields � WF ! L, we sometimes write �V for VL (the variety overL obtained by base change). For example, if V is embedded in affine or projective space,then �V is the affine or projective variety obtained by applying � to the coefficients of theequations defining V .

A regular map 'WV !W defines a regular map 'LWVL!WL which we also denote�'W�V ! �W . Note that .�'/.�Z/D �.'.Z// for any subvariety Z of V . The map �'is obtained from ' by applying � to the coefficients of the polynomials defining '.

Let ˝ � k be fields, and let � D Aut.˝=k/.An˝=k-descent system on a variety V over˝ isa family .'� /�2� of isomorphisms '� W�V ! V

satisfying the following cocycle condition:

'� ı .�'� /D '�� for all �;� 2 �:

��V �V V�'� '�

'��

Descent data 225

A model .V0;'/ of V over a subfield K of ˝ containing k splits .'� /�2� if '� D'�1 ı�' for all � fixing K:

�V �.V0˝/D V0˝ V:�' '

'�

A descent system .'� /�2� is said to be continuous if it is split by some model over asubfield K of ˝ that is finitely generated over k. A descent datum is a continuous descentsystem. A descent datum is effective if it is split by some model over k. In a given situation,we say that descent is effective or that it is possible to descend the base field if every descentdatum is effective.

Let V0 be a variety over k, and let V DV0˝ . Then V D �V because the two varieties areobtained from V0 by extension of scalars with respect to the maps k!L and k!L

��!L,

which are equal. Write '� for the identity map �V ! V ; then .'� /�2� is a descent datumon V .

Let .'� /�2� be an ˝=k descent system on a variety V , and let � 0 D Aut.˝sep=k/.Every k-automorphism of ˝ extends to a k-automorphism of ˝sep, and .'� /�2� extendsto the ˝sep=k descent system .'0� /�2� 0 on V˝sep with '0� D

�'� j˝

�˝sep . A model of V

over a subfield K of ˝ splits .'� /�2� if and only if it splits .'0� /�2� 0 . This observationsometimes allows us to assume that ˝ is separably closed.

PROPOSITION 16.16. Assume that k is the fixed field of � D Aut.˝=k/, and that .V0;'/and .V 00;'

0/ split descent data .'� /�2� and .'0� /�2� on varieties V and V 0 over ˝. Togive a regular map 0WV0 ! V 00 amounts to giving a regular map WV ! V 0 such that ı'� D '

0� ı� for all � 2 � , i.e., such that

�V'�����! V??y� ??y

�V 0'0�����! V 0

(31)

commutes for all � 2 � .

PROOF. Given 0, define to make the right hand square in

�V�'����! V0˝

' ���� V??y� ??y 0˝ ??y

�V 0�'0

����! V 00˝'0

����! V 0

commute. The left hand square is obtained from the right hand square by applying � , andso it also commutes. The outer square is (31).

In proving the converse, we may assume that ˝ is separably closed. Given , use 'and '0 to transfer to a regular map 0WV0˝ ! V 00˝ . Then the hypothesis implies that 0

commutes with the actions of � on V0.˝/ and V 00.˝/, and so is defined over k (16.9). 2

226 16. DESCENT THEORY

COROLLARY 16.17. Assume that k is the fixed field of � D Aut.˝=k/, and that .V0;'/splits the descent datum .'� /�2� . Let W be a variety over k. To give a regular mapW ! V0 (resp. V0!W ) amounts to giving a regular map WW˝! V (resp. WV !W˝)compatible with the descent datum, i.e., such that '� ı� D (resp. ı'� D � ).

PROOF. Special case of the proposition in which W˝ is endowed with its natural descentdatum. 2

REMARK 16.18. Proposition 16.16 implies that the functor taking a variety V over k toV˝ over ˝ endowed with its natural descent datum is fully faithful.

Let .'� /�2� be an˝=k-descent system on V . For a subvarietyW of V , we set �W D'� .�W /. Then the following diagram commutes:

�V'�����!'

Vx??S x??S�W

'� j�W�����!'

�W

LEMMA 16.19. The following hold.

(a) For all �;� 2 � and W � V , � .�W /D ��W .(b) Suppose that .'� /�2� is split by a model .V0;'/ of V over k0, and let W be a

subvariety of V . If W D '�1.W0˝/ for some subvariety W0 of V0, then �W DW

for all � 2 � ; the converse is true if ˝� D k.

PROOF. (a) By definition� .�W /D '� .�.'� .�W //D .'� ı�'� /.��W /D '�� .��W /D

��W .

In the second equality, we used that .�'/.�W /D �.'W /.(b) Let W D '�1.W0˝/. By hypothesis '� D '�1 ı�', and so�W D .'�1 ı�'/.�W /D '�1.�.'W //D '�1.�W0˝/D '

�1.W0˝/DW:

Conversely, suppose �W DW for all � 2 � . Then

'.W /D '.�W /D .�'/.�W /D �.'.W //.

Therefore, '.W / is stable under the action of � on V0˝ , and so is defined over k (see16.8). 2

For a descent system .'� /�2� on V and a regular function f on an open subset U ofV , we define �f to be the function .�f /ı'�1� on �U , so that �f .�P /D � .f .P // for allP 2 U . Then � .�f /D ��f , and so this defines an action of � on the regular functions.

The Krull topology on � is that for which the subgroups of � fixing a subfield of ˝finitely generated over k form a basis of open neighbourhoods of 1 (see FT Chapter 7). Anaction of � on an ˝-vector space V is continuous if

V D[�

V � .union over the open subgroups � of � ).

For a subfield L of ˝ containing k, let �L D Aut.˝=L/.

Descent data 227

PROPOSITION 16.20. Assume that ˝ is separably closed. A descent system .'� /�2� onan affine variety V is continuous if and only if the action of � on ˝ŒV � is continuous.

PROOF. If .'� /�2� is continuous, it is split by a model of V over a subfieldK of˝ finitelygenerated over k. By definition, �K is open, and ˝ŒV ��K contains a set ff1; : : : ;fng ofgenerators for˝ŒV � as an˝-algebra. Now˝ŒV �D

SLŒf1; : : : ;fn� where L runs over the

subfields of ˝ containing K and finitely generated over k. As LŒf1; : : : ;fn� D ˝ŒV ��L ,this shows that ˝ŒV �D

S˝ŒV ��L .

Conversely, if the action of � on ˝ŒV � is continuous, then for some subfield L of ˝finitely generated over k, ˝ŒV ��L will contain a set of generators f1; : : : ;fn for ˝ŒV � asan ˝-algebra. According to (16.3), ˝�L is a purely inseparable algebraic extension of L,and so, after replacing L with a finite extension, the embedding V ,! An defined by thefi will determine a model of V over L. This model splits .'� /�2� , which is thereforecontinuous. 2

PROPOSITION 16.21. A descent system .'� /�2� on a variety V over ˝ is continuous ifthere exists a finite set S of points in V.˝/ such that

(a) any automorphism of V fixing all P 2 S is the identity map, and(b) there exists a subfield K of ˝ finitely generated over k such that �P D P for all

� 2 � fixing K.

PROOF. Let .V0;'/ be a model of V over a subfieldK of˝ finitely generated over k. Afterpossibly replacing K by a larger finitely generated field, we may suppose (i) that �P D Pfor all � 2 � fixing K and all P 2 S (because of (b)) and (ii) that '.P / 2 V0.K/ for allP 2 S (because S is finite). Then, for P 2 S and every � fixing K,

'� .�P /defD

�P(i)D P

.�'/.�P /D �.'P /(ii)D 'P;

and so '� and '�1 ı�' are isomorphisms �V ! V sending �P to P . Therefore, '� and'�1 ı �' differ by an automorphism of V fixing the P 2 S , which implies that they areequal. This says that .V0;'/ splits .'� /�2� . 2

PROPOSITION 16.22. Let V be a variety over ˝ whose only automorphism is the identitymap. A descent datum on V is effective if V has a model over k:

PROOF. Let .V;'/ be a model of V over k. For � 2 � , the maps '� and '�1 ı�' are bothisomorphisms �V ! V , and so differ by an automorphism of V . Therefore they are equal,which says that .V;'/ splits .'� /�2� . 2

Of course, in Proposition 16.21, S doesn’t have to be a finite set of points. The propo-sition will hold with S any additional structure on V that rigidifies V (i.e., is such thatAut.V;S/D 1) and is such that .V;S/ has a model over a finitely generated extension of k.

228 16. DESCENT THEORY

Galois descent of varieties

In this subsection, ˝ is a Galois extension of k with Galois group � .

THEOREM 16.23. A descent datum .'� /�2� on a variety V is effective if V is covered byopen affines U with the property that �U D U for all � 2 � .

PROOF. Assume first that V is affine, and let AD kŒV �. A descent datum .'� /�2� definesa continuous action of � on A (see 16.20). From (16.15), we know that

c˝a 7! caW˝˝k A�! A (32)

is an isomorphism. Let V0 D SpmA� , and let ' be the isomorphism V ! V0˝ defined by(32). Then .V0;'/ splits the descent datum.

In the general case, write V as a finite union of open affines Ui such that �Ui D Ui forall � 2 � . Then V is the variety over˝ obtained by patching the Ui by means of the maps

Ui - Ui \Uj ,! Uj : (33)

Each intersection Ui \Uj is again affine (4.27), and so the system (33) descends to k. Thevariety over k obtained by patching the descended system is a model of V over k splittingthe descent datum. 2

COROLLARY 16.24. If each finite set of points of V.˝sep/ is contained in an open affinesubvariety of V˝sep , then every descent datum on V is effective.

PROOF. As we noted before, an ˝=k-descent datum for V extends in a natural way to an˝sep=k-descent datum for V˝sep , and if a model .V0;'/ over k splits the second descentdatum, then it also splits the first. Thus, we may suppose that ˝ is separably closed.

Let .'� /�2� be a descent datum on V , and let U be a subvariety of V . By definition,.'� / is split by a model .V1;'/ of V over some finite extension k1 of k. After possiblyreplacing k1 with a larger finite extension, there will exist a subvariety U1 of V1 suchthat '.U / D U1˝ . Now (16.19b) shows that �U depends only on the coset �� where�D Gal.˝=k1/. In particular, f�U j � 2 � g is finite. The subvariety

T�2�

�U is stableunder � , and so (see 16.8, 16.19) � .

T�2�

�U/D .T�2�

�U/ for all � 2 � .Let P 2 V . Because f�P j � 2 � g is finite, it is contained in an open affine U of V .

Now U 0 DT�2�

�U is an open affine in V containing P and such that �U 0 D U 0 for all� 2 � . It follows that the variety V satisfies the hypothesis of Theorem 16.23. 2

COROLLARY 16.25. Descent is effective in each of the following two cases:

(a) V is quasiprojective, or(b) an affine algebraic group G acts transitively on V .

PROOF. (a) Apply (6.25) (whose proof applies unchanged over any infinite base field).(b) We may assume ˝ to be separably closed. Let S be a finite set of points of V.˝/,

and let U be an open affine in V . For each P 2 S , there is a nonempty open subvariety GPof G such that GP �P � U . Because ˝ is separably closed, there exists a g 2 .

TP2S GP �

P /.˝/ (see 11.15). Now g�1U is an open affine containing S . 2

Weil restriction 229

Weil restriction

Let K=k be a finite extension of fields, and let V be a variety over K. A pair .V�;'/consisting of a variety V� over k and a regular map 'WV�K ! V is called the K=k-Weilrestriction of V if it has the following universal property: for any variety T over k andregular map '0WTK! V , there exists a unique regular map WT ! V (of k-varieties) suchthat ' ı K D '0, i.e., given

TK

V�K V

'0

'

there exists a unique

T

V�

such that

TK

V�K V

K'0

'

commutes.

In other words, .V�;'/ is the K=k-Weil restriction of V if ' defines an isomorphism

Mork.T;V�/!MorK.TK ;V /

(natural in the k-variety T ); in particular,

V�.A/' V.K˝k A/

(natural in the affine k-algebra A). If it exists, the K=k-Weil restriction of V is uniquelydetermined by its universal property (up to a unique isomorphism).

When .V�;'/ is the K=k-Weil restriction of V , the variety V� is said to have beenobtained from V by (Weil) restriction of scalars or by restriction of the base field:

PROPOSITION 16.26. If V satisfies the hypothesis of (16.24) (for example, if V is quasipro-jective) and K=k is separable, then the K=k-Weil restriction exists.

PROOF. Let ˝ be a Galois extension of k large enough to contain all conjugates of K,i.e., such that ˝˝k K '

Q� WK!˝ �K. Let V 0 D

Q�V — this is a variety over ˝. For

� 2Gal.˝=k/, define '� W�V 0! V 0 to be the regular map that acts on the factor �.�V / asthe canonical isomorphism �.�V /' .��/V . Then .'� /�2Gal.˝=k/ is a descent datum, andso defines a model .V�;'�/ of V 0 over k.

Choose a �0WK ! ˝. The projection map V 0! �0V is invariant under the action ofGal.˝=�0K/, and so defines a regular map .V�/�0K ! �0V (16.9), and hence a regularmap 'WV�K ! V . It is easy to check that this has the correct universal property. 2

Generic fibres and specialization

In this subsection, k is an algebraically closed field.Let 'WV ! U be a dominant map with U irreducible, and let K D k.U /. Then there

is a regular map 'K WVK ! SpmK, called the generic fibre of '. For example, if V andU are affine, so that ' corresponds to an injective homomorphism of rings f WA! B , then'K corresponds to A˝kK ! B˝kK. In the general case, we replace U with any openaffine and write V as a finite union of affines V D

Si Vi ; then VK D

Si ViK .

Let K be a field finitely generated over k, and let V be a variety over K. For anyirreducible k-variety U with k.U / D K, there will exist a dominant map 'WV ! U withgeneric fibre V . For example, we can take U D Spm.A/ where A is any finitely generated

230 16. DESCENT THEORY

k-subalgebra of K containing a set of generators for K and containing the coefficients ofsome set of polynomials defining V . Let P be a point in the image of '. Then the fibre ofV over P is a variety V.P / over k, called the specialization of V at P .

Similar statements are true for morphisms of varieties.

Rigid descent

LEMMA 16.27. Let V andW be varieties over an algebraically closed field k. If V andWbecome isomorphic over some field containing k, then they are already isomorphic over k.

PROOF. The hypothesis implies that, for some fieldK finitely generated over k, there existsan isomorphism 'WVK ! WK . Let U be an affine k-variety such that k.U / D K. Afterpossibly replacingU with an open subset, we can extend ' to an isomorphism 'U WU �V !

U �W . The fibre of 'U at any point of U is an isomorphism V !W . 2

Consider fields ˝ �K1;K2 � k. Recall (11.1) that K1 and K2 are said to be linearlydisjoint over k if the homomorphismP

ai ˝bi 7!Paibi WK1˝kK2!K1 �K2

is injective.

LEMMA 16.28. Let˝ � k be algebraically closed fields, and let V be a variety over˝. Ifthere exist models of V over subfields K1;K2 of ˝ finitely generated over k and linearlydisjoint over k, then there exists a model of V over k.

PROOF. The model of V over K1 extends to a model over an irreducible affine variety U1with k.U1/DK1, i.e., there exists a surjective map V1! U1 of k-varieties whose genericfibre is a model of V over K1. A similar statement applies to the model over K2. BecauseK1 and K2 are linearly disjoint, K1˝k K2 is an integral domain with field of fractionsk.U1�U2/. From the map V1! U1, we get a map V1�U2! U1�U2, and similarly forV2.

Assume initially that V1�U2 and U1�V2 are isomorphic over U1�U2, so that we havea commutative diagram:

V1 V1�U2 U1�V2 V2

U1 U1�U2 U2

�

Let P be a point ofU1. When we pull back the triangle to the subvariety P �U2 ofU1�U2,we get the diagram at left below. Note that P �U2 ' U2 and that P ' Spmk (because k isalgebraically closed).

V.P /�U2 P �V2 V.P /K2 V2K2

P �U2 Spm.K2/

� �

Rigid descent 231

The generic fibre of this diagram is the diagram at right. Here V1.P /K2 is the variety overK2 obtained from V1.P / by extension of scalars k!K2. As V2K2 is a model V over K2,it follows that V1.P / is a model of V over k.

We now prove the general case. The varieties .V1�U2/k.U1�U2/ and .U1�V2/k.U1�U2/become isomorphic over some finite field extension L of k.U1�U2/. Let NU be the normal-ization1 ofU1�U2 inL, and letU be a dense open subset of NU such that some isomorphismof .V1�U2/L with .U1�V2/L extends to an isomorphism over U . The going-up theorem(8.8) shows that NU ! U1�U2 is surjective, and so the image U 0 of U in U1�U2 containsa nonempty (hence dense) open subset of U1�U2 (see 10.2). In particular, U 0 contains asubset P �U 02 with U 02 a nonempty open subset of U2. Now the previous argument givesus varieties V1.P /K2 and V2K2 over K2 that become isomorphic over k.U 00/ where U 00 isthe inverse image of P �U 02 in NU . As k.U 00/ is a finite extension of K2, this again showsthat V1.P / is a model of V over k. 2

EXAMPLE 16.29. Let E be an elliptic curve over ˝ with j -invariant j.E/. There existsa model of E over a subfield K of ˝ if and only if j.E/ 2 K. If j.E/ is transcendental,then any two such fields contain k.j.E//, and so can’t be linearly disjoint. Therefore, thehypothesis in the proposition implies j.E/ 2 k, and so E has a model over k.

LEMMA 16.30. Let˝ be algebraically closed of infinite transcendence degree over k, andassume that k is algebraically closed in ˝. For any K �˝ finitely generated over k, thereexists a � 2 Aut.˝=k/ such that K and �K are linearly disjoint over k:

PROOF. Let a1; : : : ;an be a transcendence basis for K=k, and extend it to a transcendencebasis a1; : : : ;an;b1; : : : ;bn; : : : of˝=k. Let � be any permutation of the transcendence basissuch that �.ai /D bi for all i . Then � defines a k-automorphism of k.a1; : : :an;b1; : : : ;bn; : : :/,which we extend to an automorphism of ˝.

Let K1 D k.a1; : : : ;an/. Then �K1 D k.b1; : : : ;bn/, and certainly K1 and �K1 arelinearly disjoint. In particular,K1˝k �K1 is an integral domain. Because k is algebraicallyclosed in K, K˝k �K is an integral domain (cf. 11.5). This implies that K and �K arelinearly disjoint. 2

LEMMA 16.31. Let ˝ � k be algebraically closed fields such that ˝ is of infinite tran-scendence degree over k, and let V be a variety over˝. If V is isomorphic to �V for every� 2 Aut.˝=k/, then V has a model over k.

PROOF. There will exist a model V0 of V over a subfieldK of˝ finitely generated over k.According to Lemma 16.30, there exists a � 2 Aut.˝=k/ such that K and �K are linearlydisjoint. Because V � �V , �V0 is a model of V over �K, and we can apply Lemma 16.28.2

In the next two theorems, ˝ � k are fields such that the fixed field of � D Aut.˝=k/is k and ˝ is algebraically closed

THEOREM 16.32. Let V be a quasiprojective variety over˝, and let .'� /�2� be a descentsystem for V . If the only automorphism of V is the identity map, then V has a model overk splitting .'� /.

1Let U1�U2 D SpmC ; then NU D Spm NC , where NC is the integral closure of C in L.

232 16. DESCENT THEORY

PROOF. According to Lemma 16.31, V has a model .V0;'/ over the algebraic closure kal

of k in ˝, which (see the proof of 16.22) splits .'� /�2Aut.˝=kal/.

Now '0�defD '�1 ı '� ı �' is stable under Aut.˝=kal/, and hence is defined over kal

(16.9). Moreover, '0� depends only on the restriction of � to kal, and .'0� /�2Gal.kal=k/ is adescent system for V0. It is continuous by (16.21), and so V0 has a model .V00;'0/ over ksplitting .'0� /�2Gal.kal=k/. Now .V00;' ı'

0˝/ splits .'� /�2Aut.˝=k/. 2

We now consider pairs .V;S/ where V is a variety over ˝ and S is a family of pointsS D .Pi /1�i�n of V indexed by Œ1;n�. A morphism .V;.Pi /1�i�n/! .W;.Qi /1�i�n/ isa regular map 'WV !W such that '.Pi /DQi for all i .

THEOREM 16.33. Let V be a quasiprojective variety over ˝, and let .'� /�2Aut.˝=k/ be adescent system for V . Let S D .Pi /1�i�n be a finite set of points of V such that

(a) the only automorphism of V fixing each Pi is the identity map, and(b) there exists a subfield K of ˝ finitely generated over k such that �P D P for all

� 2 � fixing K.

Then V has a model over k splitting .'� /.

PROOF. Lemmas 16.27–16.31 all hold for pairs .V;S/ (with the same proofs), and so theproof of Theorem 16.32 applies. 2

EXAMPLE 16.34. Theorem 16.33 can be used to prove that certain abelian varieties at-tached to algebraic varieties in characteristic zero, for example, the generalized Jacobianvarieties, are defined over the same field as the variety.2 We illustrate this with the usualJacobian variety J of a complete nonsingular curve C . For such a curve C over C, there isa principally polarized abelian variety J.C / such that, as a complex manifold,

J.C /.C/D � .C;˝1/_=H1.C;Z/.

The association C 7! J.C / is a functorial, and so a descent datum .'� /�2Aut.˝=k/ on Cdefines a descent system on J.C /. It is known that if we take S to be the set of pointsof order 3 on J.C /, then condition (a) of the theorem is satisfied (see, for example, Milne19863, 17.5), and condition (b) can be seen to be satisfied by regarding J.C / as the Picardvariety of C .

Weil’s descent theorems

THEOREM 16.35. Let k be a finite separable extension of a field k0, and let I be theset of k-homomorphisms k ! kal

0 . Let V be a quasiprojective variety over k; for eachpair .�;�/ of elements of I , let '�;� be an isomorphism �V ! �V (of varieties over kal

0 ).Then there exists a variety V0 over k0 and an isomorphism 'WV0k ! V such that '�;� D�' ı .�'/�1 for all �;� 2 I if and only if the '�;� are defined over ksep

0 and satisfy thefollowing conditions:

(a) '�;� D '�;� ı'�;� for all �;�;� 2 I ;

2This was pointed out to me by Niranjan Ramachandran.3Milne, J.S., Abelian varieties, in Arithmetic Geometry, Springer, 1986.

Weil’s descent theorems 233

(b) '�!;�! D !'�;� for all �;� 2 I and all k0-automorphisms ! of kal0 over k0.

Moreover, when this is so, the pair .V0;'/ is unique up to isomorphism over k0, and V0 isquasiprojective or quasi-affine if V is.

PROOF. This is Theorem 3 of Weil 1956,4 p515. It is essentially a restatement of (a) ofCorollary 16.25 (and .V0;'/ is unique up to a unique isomorphism over k0). 2

An extension K of a field k is said to be regular if it is finitely generated, admits aseparating transcendence basis, and k is algebraically closed in K. These are preciselythe fields that arise as the field of rational functions on geometrically irreducible algebraicvariety over k:

Let k be a field, and let k.t/, t D .t1; : : : ; tn/; be a regular extension of k (in Weil’sterminology, t is a generic point of a variety over k). By k.t 0/ we shall mean a fieldisomorphic to k.t/ by t 7! t 0, and we write k.t; t 0/ for the field of fractions of k.t/˝k k.t 0/.5

When Vt is a variety over k.t/, we shall write Vt 0 for the variety over k.t 0/ obtained from Vtby base change with respect to t 7! t 0Wk.t/! k.t 0/. Similarly, if ft denotes a regular mapof varieties over k.t/, then ft 0 denotes the regular map over k.t 0/ obtained by base change.Similarly, k.t 00/ is a second field isomorphic to k.t/ by t 7! t 00 and k.t; t 0; t 00/ is the field offractions of k.t/˝k k.t 0/˝k k.t 00/.

THEOREM 16.36. With the above notations, let Vt be a quasiprojective variety over k.t/;for each pair .t; t 0/, let 't 0;t be an isomorphism Vt ! Vt 0 defined over k.t; t 0/. Then thereexists a variety V defined over k and an isomorphism 't WVk.t/! Vt (of varieties over k.t/)such that 't 0;t D 't 0 ı'�1t if and only if 't 0;t satisfies the following condition:

't 00;t D 't 00;t 0 ı't 0;t (isomorphism of varieties over k.t; t 0; t 00/:

Moreover, when this is so, the pair .V;'t / is unique up to an isomorphism over k, and V isquasiprojective or quasi-affine if V is.

PROOF. This is Theorem 6 and Theorem 7 of Weil 1956, p522. 2

THEOREM 16.37. Let ˝ be an algebraically closed field of infinite transcendence degreeover a perfect field k. Then descent is effective for quasiprojective varieties over ˝.

PROOF. Let .'� / be a descent datum on a variety V over˝. Because .'� / is continuous, itis split by a model of V over some subfield K of ˝ finitely generated over k. Let k0 be thealgebraic closure of k in K; then k0 is a finite extension of k and K is a regular extensionof k. Write K D k.t/, and let .Vt ;'0/ be a model of V over k.t/ splitting .'� /. Accordingto Lemma 16.30, there exists a � 2Aut.˝=k/ such that �k.t/D k.t 0/ and k.t/ are linearlydisjoint over k. The isomorphism

Vt˝'0

�! V'�1��! �V

.�'0/�1

�! Vt 0;˝

4Weil, Andre, The field of definition of a variety. Amer. J. Math. 78 (1956), 509–524.5If k.t/ and k.t 0/ are linearly disjoint subfields of some large field ˝, then k.t; t 0/ is the subfield of ˝

generated over k by t and t 0.

234 16. DESCENT THEORY

is defined over k.t; t 0/ and satisfies the conditions of Theorem 16.36. Therefore, there existsa model .W;'/ of V over k0 splitting .'� /�2Aut.˝=k.t/.

For �;� 2 Aut.˝=k/, let '�;� be the composite of the isomorphisms

�W�'�! �V

'��! V

'�1��! �V

�'�! �W .

Then '�;� is defined over the algebraic closure of k in ˝ and satisfies the conditions ofTheorem 16.35, which gives a model of W over k splitting .'� /�2Aut.˝=k/: 2

Restatement in terms of group actions

In this subsection,˝ � k are fields such that kD˝� and˝ is algebraically closed. Recallthat for any variety V over k, there is a natural action of � on V.˝/. In this subsection, wedescribe the essential image of the functor

fquasiprojective varieties over kg ! fquasiprojective varieties over ˝C action of � g:

In other words, we determine which pairs .V;�/; with V a quasiprojective variety over ˝and � an action of � on V.˝/,

.�;P / 7! � �P W� �V.˝/! V.˝/;

arise from a variety over k. There are two obvious necessary conditions for this.

Regularity condition

Obviously, the action should recognize that V.˝/ is not just a set, but rather the set ofpoints of an algebraic variety. For � 2 � , let �V be the variety obtained by applying � tothe coefficients of the equations defining V , and for P 2 V.˝/ let �P be the point on �Vobtained by applying � to the coordinates of P .

DEFINITION 16.38. We say that the action � is regular if the map

�P 7! � �P W.�V /.˝/! V.˝/

is regular isomorphism for all � .

A priori, this is only a map of sets. The condition requires that it be induced by a regularmap '� W�V ! V . If V D V0˝ for some variety V0 defined over k, then �V D V , and '�is the identity map, and so the condition is clearly necessary.

REMARK 16.39. The maps '� satisfy the cocycle condition '� ı�'� D '�� . In particular,'� ı �'��1 D id, and so if � is regular, then each '� is an isomorphism, and the family.'� /�2� is a descent system. Conversely, if .'� /�2� is a descent system, then

� �P D '� .�P /

defines a regular action of � on V.˝/. Note that if �$ .'� /, then � �P D�P .

Restatement in terms of group actions 235

Continuity condition

DEFINITION 16.40. We say that the action � is continuous if there exists a subfield L of˝ finitely generated over k and a model V0 of V over L such that the action of � .˝=L/ isthat defined by V0.

For an affine variety V , an action of � on V gives an action of � on ˝ŒV �, and oneaction is continuous if and only if the other is.

Continuity is obviously necessary. It is easy to write down regular actions that fail it,and hence don’t arise from varieties over k.

EXAMPLE 16.41. The following are examples of actions that fail the continuity condition((b) and (c) are regular).

(a) Let V D A1 and let � be the trivial action.(b) Let ˝=k D Qal=Q, and let N be a normal subgroup of finite index in Gal.Qal=Q/

that is not open,6 i.e., that fixes no extension of Q of finite degree. Let V be the zero-dimensional variety over Qal with V.Qal/D Gal.Qal=Q/=N with its natural action.

(c) Let k be a finite extension of Qp, and let V D A1. The homomorphism k� !

Gal.kab=k/ can be used to twist the natural action of � on V.˝/.

Restatement of the main theorems

Let ˝ � k be fields such that k is the fixed field of � D Aut.˝=k/ and ˝ is algebraicallyclosed.

THEOREM 16.42. Let V be a quasiprojective variety over ˝, and let � be a regular actionof � on V.˝/. Let S D .Pi /1�i�n be a finite set of points of V such that

(a) the only automorphism of V fixing each Pi is the identity map, and(b) there exists a subfield K of ˝ finitely generated over k such that � �P D P for all

� 2 � fixing K.

Then � arises from a model of V over k.

PROOF. This a restatement of Theorem 16.33. 2

THEOREM 16.43. Let V be a quasiprojective variety over ˝ with an action � of � . If �is regular and continuous, then � arises from a model of V over k in each of the followingcases:

(a) ˝ is algebraic over k, or(b) ˝ is has infinite transcendence degree over k.

PROOF. Restatements of (16.23, 16.25) and of (16.37). 2

The condition “quasiprojective” is necessary, because otherwise the action may notstabilize enough open affine subsets to cover V .

6For a proof that such subgroups exist, see FT 7.25.

236 16. DESCENT THEORY

Faithfully flat descent

Recall that a homomorphism f WA! B of rings is flat if the functor “extension of scalars”M 7! B˝AM is exact. It is faithfully flat if a sequence

0!M 0!M !M 00! 0

of A-modules is exact if and only if

0! B˝AM0! B˝AM ! B˝AM

00! 0

is exact. For a field k, a homomorphism k! A is always flat (because exact sequences ofk-vector spaces are split-exact), and it is faithfully flat if A¤ 0.

The next theorem and its proof are quintessential Grothendieck.

THEOREM 16.44. If f WA! B is faithfully flat, then the sequence

0! Af�! B

d0

�! B˝2! �� � ! B˝rdr�1

�! B˝rC1! �� �

is exact, where

B˝r D B˝AB˝A � � �˝AB (r times)

d r�1 DP.�1/iei

ei .b0˝�� �˝br�1/D b0˝�� �˝bi�1˝1˝bi ˝�� �˝br�1:

PROOF. It is easily checked that d r ıd r�1 D 0. We assume first that f admits a section,i.e., that there is a homomorphism gWB ! A such that g ı f D 1, and we construct acontracting homotopy kr WB˝rC2! B˝rC1. Define

kr.b0˝�� �˝brC1/D g.b0/b1˝�� �˝brC1; r � �1:

It is easily checked that

krC1 ıdrC1Cd r ıkr D 1; r � �1,

and this shows that the sequence is exact.Now let A0 be an A-algebra. Let B 0 D A0˝A B and let f 0 D 1˝ f WA0 ! B 0. The

sequence corresponding to f 0 is obtained from the sequence for f by tensoring with A0

(because B˝r ˝A0 Š B 0˝f etc.). Thus, if A0 is a faithfully flat A-algebra, it suffices to

prove the theorem for f 0. Take A0 D B , and then bf7! b˝ 1WB ! B˝AB has a section,

namely, g.b˝b0/D bb0, and so the sequence is exact. 2

THEOREM 16.45. If f WA!B is faithfully flat and M is an A-module, then the sequence

0!M1˝f�! M ˝AB

1˝d0

�! M ˝AB˝2! �� � !M ˝B B

˝r 1˝dr�1

�! B˝rC1! �� �

is exact.

PROOF. As in the above proof, one may assume that f has a section, and use it to constructa contracting homotopy. 2

Faithfully flat descent 237

REMARK 16.46. Let f WA! B be a faithfully flat homomorphism, and let M be an A-module. Write M 0 for the B-module f�M D B ˝AM . The module e0�M 0 D .B ˝AB/˝BM

0 may be identified with B˝AM 0 where B˝AB acts by .b1˝ b2/.b˝m/ Db1b˝ b2m, and e1�M 0 may be identified with M 0˝A B where B ˝A B acts by .b1˝b2/.m˝ b/ D b1m˝ b2b. There is a canonical isomorphism �We1�M

0! e0�M0 arising

frome1�M

0D .e1f /�M D .e0f /�M D e0�M

0I

explicitly, it is the map

.b˝m/˝b0 7! b˝ .b0˝m/WM 0˝AB! B˝AM:

Moreover, M can be recovered from the pair .M 0;�/ because

M D fm 2M 0 j 1˝mD �.m˝1/g:

Conversely, every pair .M 0;�/ satisfying certain obvious conditions does arise in this wayfrom an A-module. Given �WM 0˝AB! B˝AM

0, define

�1WB˝AM0˝AB! B˝AB˝AM

0

�2WM0˝AB˝AB! B˝AB˝AM

0;

�3WM0˝AB˝AB! B˝AM

0˝AB

by tensoring � with idB in the first, second, and third positions respectively. Then a pair.M 0;�/ arises from an A-module M as above if and only if �2 D �1 ı�3. The necessity iseasy to check. For the sufficiency, define

M D fm 2M 0 j 1˝mD �.m˝1/g:

There is a canonical map b˝m 7! bmWB˝AM !M 0, and it suffices to show that this isan isomorphism (and that the map arising from M is �). Consider the diagram

M 0˝AB

˛˝1

⇒ˇ˝1

B˝AM0˝AB

# � # �1

B˝AM0

e0˝1

⇒e1˝1

B˝AB˝AM0

in which ˛.m/D 1˝m and ˇ.m/D �.m/˝1. As the diagram commutes with either theupper of the lower horizontal maps (for the lower maps, this uses the relation �2D �1 ı�3),� induces an isomorphism on the kernels. But, by defintion of M , the kernel of the pair.˛˝1;ˇ˝1/ is M ˝AB , and, according to (16.45), the kernel of the pair .e0˝1;e1˝1/is M 0. This essentially completes the proof.

A regular map 'WW ! V of algebraic spaces is faithfully flat if it is surjective on theunderlying sets and O'.P /!OP is flat for all P 2W , and it is affine if the inverse imagesof open affines in V are open affines in W .

238 16. DESCENT THEORY

THEOREM 16.47. Let 'WW ! V be a faithfully flat map of algebraic spaces. To give analgebraic space U affine over V is the same as to give an algebraic space U 0 affine over Wtogether with an isomorphism �Wp�1U

0! p�2U0 satisfying

p�31.�/D p�32.�/ıp

�21.�/:

Here pj i denotes the projection W �W �W ! W �W such that pj i .w1;w2;w3/ D.wj ;wi ).

PROOF. When W and V are affine, (16.46) gives a similar statement for modules, hencefor algebras, and hence for algebraic spaces. 2

EXAMPLE 16.48. Let � be a finite group, and regard it as an algebraic group of dimension0. Let V be an algebraic space over k. An algebraic space Galois over V with Galois group� is a finite mapW ! V to algebraic space together with a regular mapW �� !W suchthat

(a) for all k-algebras R, W.R/�� .R/!W.R/ is an action of the group � .R/ on theset W.R/ in the usual sense, and the map W.R/! V.R/ is compatible with theaction of � .R/ on W.R/ and its trivial action on V.R/, and

(b) the map .w;�/ 7! .w;w�/WW �� !W �V W is an isomorphism.

Then there is a commutative diagram7

V W ⇔ W �� � � �

W �� 2

jj jj # ' # '

V W ⇔ W �V W � � �

W �V W �V W

The vertical isomorphisms are

.w;�/ 7! .w;w�/

.w;�1;�2/ 7! .w;w�1;w�1�2/:

Therefore, in this case, Theorem 16.47 says that to give an algebraic space affine over Vis the same as to give an algebraic space affine over W together with an action of � on itcompatible with that on W . When we take W and V to be the spectra of fields, then thisbecomes affine case of Theorem 16.23.

EXAMPLE 16.49. In Theorem 16.47, let ' be the map corresponding to a regular extensionof fields k! k.t/. This case of Theorem 16.47 coincides with the affine case of Theorem16.36 except that the field k.t; t 0/ has been replaced by the ring k.t/˝k k.t 0/.

NOTES. The paper of Weil cited in subsection on Weil’s descent theorems is the first importantpaper in descent theory. Its results haven’t been superseded by the many results of Grothendieck ondescent. In Milne 19998, Theorem 16.33 was deduced from Weil’s theorems. The present more ele-mentary proof was suggested by Wolfart’s elementary proof of the ‘obvious’ part of Belyi’s theorem(Wolfart 19979; see also Derome 200310).

7See Milne, J. S., Etale cohomology. Princeton, 1980, p100.8Milne, J. S., Descent for Shimura varieties. Michigan Math. J. 46 (1999), no. 1, 203–208.9Wolfart, Jurgen. The “obvious” part of Belyi’s theorem and Riemann surfaces with many automorphisms.

Geometric Galois actions, 1, 97–112, London Math. Soc. Lecture Note Ser., 242, Cambridge Univ. Press,Cambridge, 1997.

10Derome, G., Descente algebriquement close, J. Algebra, 266 (2003), 418–426.

CHAPTER 17Lefschetz Pencils (Outline)

In this chapter, we see how to fibre a variety over P1 in such a way that the fibres have onlyvery simple singularities. This result sometimes allows one to prove theorems by inductionon the dimension of the variety. For example, Lefschetz initiated this approach in order tostudy the cohomology of varieties over C.

Throughout this chapter, k is an algebraically closed field.

Definition

A linear form H DPmiD0aiTi defines a hyperplane in Pm, and two linear forms define the

same hyperplane if and only if one is a nonzero multiple of the other. Thus the hyperplanesin Pm form a projective space, called the dual projective space LPm.

A line D in LPm is called a pencil of hyperplanes in Pm. If H0 and H1 are any twodistinct hyperplanes in D, then the pencil consists of all hyperplanes of the form ˛H0C

ˇH1 with .˛Wˇ/ 2 P1.k/. If P 2H0\H1, then it lies on every hyperplane in the pencil— the axis A of the pencil is defined to be the set of such P . Thus

ADH0\H1 D\t2DHt :

The axis of the pencil is a linear subvariety of codimension 2 in Pm, and the hyperplanes ofthe pencil are exactly those containing the axis. Through any point in Pm not on A, therepasses exactly one hyperplane in the pencil. Thus, one should imagine the hyperplanes inthe pencil as sweeping out Pm as they rotate about the axis.

Let V be a nonsingular projective variety of dimension d � 2, and embed V in someprojective space Pm. By the square of an embedding, we mean the composite of V ,! Pmwith the Veronese mapping (6.20)

.x0W : : : Wxm/ 7! .x20 W : : : Wxixj W : : : Wx2m/WP

m! P

.mC2/.mC1/2 :

DEFINITION 17.1. A line D in LPm is said to be a Lefschetz pencil for V � Pm if

(a) the axis A of the pencil .Ht /t2D cuts V transversally;(b) the hyperplane sections Vt

defD V \Ht of V are nonsingular for all t in some open

dense subset U of DI(c) for t … U , Vt has only a single singularity, and the singularity is an ordinary double

point.

239

240 17. LEFSCHETZ PENCILS (OUTLINE)

Condition (a) means that, for every point P 2 A\V , TgtP .A/\TgtP .V / has codi-mension 2 in TgtP .V /, the tangent space to V at P .

Condition (b) means that, except for a finite number of t , Ht cuts V transversally, i.e.,for every point P 2Ht \V , TgtP .Ht /\TgtP .V / has codimension 1 in TgtP .V /.

A point P on a variety V of dimension d is an ordinary double point if the tangentcone at P is isomorphic to the subvariety of AdC1 defined by a nondegenerate quadraticform Q.T1; : : : ;TdC1/, or, equivalently, if

OOV;P � kŒŒT1; : : : ;TdC1��=.Q.T1; : : : ;TdC1//:

THEOREM 17.2. There exists a Lefschetz pencil for V (after possibly replacing the pro-jective embedding of V by its square).

PROOF. (Sketch). LetW � V � LPm be the closed variety whose points are the pairs .x;H/such that H contains the tangent space to V at x. For example, if V has codimension 1 inPm, then .x;H/ 2 Y if and only if H is the tangent space at x. In general,

.x;H/ 2W ” x 2H and H does not cut V transversally at x:

The image ofW in LPm under the projection V � LPm! LPm is called the dual variety LV of V .The fibre of W ! V over x consists of the hyperplanes containing the tangent space at x,and these hyperplanes form an irreducible subvariety of LPm of dimensionm� .dimV C1/;it follows that W is irreducible, complete, and of dimension m� 1 (see 10.11) and that Vis irreducible, complete, and of codimension � 1 in LPm (unless V D Pm, in which caseit is empty). The map 'W W ! LV is unramified at .x;H/ if and only if x is an ordinarydouble point on V \H (see SGA 7, XVII 3.71). Either ' is generically unramified, or itbecomes so when the embedding is replaced by its square (so, instead of hyperplanes, weare working with quadric hypersurfaces) (ibid. 3.7). We may assume this, and then (ibid.3.5), one can show that for H 2 LV r LVsing, V \H has only a single singularity and thesingularity is an ordinary double point. Here LVsing is the singular locus of LV .

By Bertini’s theorem (Hartshorne 1977, II 8.18) there exists a hyperplane H0 such thatH0\V is irreducible and nonsingular. Since there is an .m�1/-dimensional space of linesthroughH0, and at most an .m�2/-dimensional family will meet Vsing, we can chooseH1so that the line D joining H0 and H1 does not meet LVsing. Then D is a Lefschetz pencilfor V: 2

THEOREM 17.3. Let D D .Ht / be a Lefschetz pencil for V with axis A D \Ht . Thenthere exists a variety V � and maps

V V ���!D:

such that:

(a) the map V �! V is the blowing up of V along A\V I1Groupes de monodromie en geometrie algebrique. Seminaire de Geometrie Algebrique du Bois-Marie

1967–1969 (SGA 7). Dirige par A. Grothendieck. Lecture Notes in Mathematics, Vol. 288, 340. Springer-Verlag, Berlin-New York, 1972, 1973.

Definition 241

(b) the fibre of V �!D over t is Vt D V \Ht .

Moreover, � is proper, flat, and has a section.

PROOF. (Sketch) Through each point x of V rA\V , there will be exactly one Hx in D.The map

'WV rA\V !D, x 7!Hx;

is regular. Take the closure of its graph �' in V �D; this will be the graph of �: 2

REMARK 17.4. The singular Vt may be reducible. For example, if V is a quadric surfacein P3, then Vt is curve of degree 2 in P2 for all t , and such a curve is singular if and only ifit is reducible (look at the formula for the genus). However, if the embedding V ,! Pm isreplaced by its cube, this problem will never occur.

References

The only modern reference I know of is SGA 7, Expose XVII.

CHAPTER 18Algebraic Schemes and Algebraic

Spaces

In this course, we have attached an affine algebraic variety to any algebra finitely generatedover a field k. For many reasons, for example, in order to be able to study the reductionof varieties to characteristic p ¤ 0, Grothendieck realized that it is important to attach ageometric object to every commutative ring. Unfortunately, A 7! spmA is not functorialin this generality: if 'WA! B is a homomorphism of rings, then '�1.m/ for m maximalneed not be maximal — consider for example the inclusion Z ,!Q. Thus he was forced toreplace spm.A/ with spec.A/, the set of all prime ideals in A. He then attaches an affinescheme Spec.A/ to each ring A, and defines a scheme to be a locally ringed space thatadmits an open covering by affine schemes.

There is a natural functor V 7! V � from the category of algebraic spaces over k tothe category of schemes of finite-type over k, which is an equivalence of categories. Thealgebraic varieties correspond to geometrically reduced schemes. To construct V � fromV , one only has to add one point pZ for each irreducible closed subvariety Z of V ofdimension > 0; in other words, V � is the set of irreducible closed subsets of V (and V isthe subset of V � of zero-dimensional irreducible closed subsets of V , i.e., points). For anyopen subset U of V , let U � be the subset of V � containing the points of U together withthe points pZ such that U \Z is nonempty. Thus, U 7! U � is a bijection from the set ofopen subsets of V to the set of open subsets of V �. Moreover, � .U �;OV �/D � .U;OV /for each open subset U of V . Therefore the topologies and sheaves on V and V � are thesame — only the underlying sets differ. For a closed irreducible subset Z of V , the localring OV �;pZ D lim

�!U\Z¤;� .U;OU /. The reverse functor is even easier: simply omit the

nonclosed points from the base space.1

Every aspiring algebraic and (especially) arithmetic geometer needs to learn the basictheory of schemes, and for this I recommend reading Chapters II and III of Hartshorne1997.

1Some authors call a geometrically reduced scheme of finite-type over a field a variety. Despite their simi-larity, it is important to distinguish such schemes from varieties (in the sense of these notes). For example, ifWandW 0 are subvarieties of a variety, their intersection in the sense of schemes need not be reduced, and so maydiffer from their intersection in the sense of varieties. For example, if W D V.a/�An and W 0 D V.a0/�An0

with a and a0 radical, then the intersection W and W 0 in the sense of schemes is SpeckŒX1; : : : ;XnCn0 �=.a;a0/while their intersection in the sense of varieties is SpeckŒX1; : : : ;XnCn0 �=rad.a;a0/ (and their intersection inthe sense of algebraic spaces is SpmkŒX1; : : : ;XnCn0 �=.a;a0/.

243

APPENDIX ASolutions to the exercises

1-1 Use induction on n. For n D 1, use that a nonzero polynomial in one variable hasonly finitely many roots (which follows from unique factorization, for example). Nowsuppose n > 1 and write f D

PgiX

in with each gi 2 kŒX1; : : : ;Xn�1�. If f is not the zero

polynomial, then some gi is not the zero polynomial. Therefore, by induction, there exist.a1; : : : ;an�1/ 2 k

n�1 such that f .a1; : : : ;an�1;Xn/ is not the zero polynomial. Now, bythe degree-one case, there exists a b such that f .a1; : : : ;an�1;b/¤ 0.

1-2 .XC2Y;Z/; Gaussian elimination (to reduce the matrix of coefficients to row echelonform); .1/, unless the characteristic of k is 2, in which case the ideal is .XC1;ZC1/.

2-1 W D Y -axis, and so I.W /D .X/. Clearly,

.X2;XY 2/� .X/� rad.X2;XY 2/

and rad..X//D .X/. On taking radicals, we find that .X/D rad.X2;XY 2/.

2-2 The d �d minors of a matrix are polynomials in the entries of the matrix, and the setof matrices with rank � r is the set where all .rC1/� .rC1/ minors are zero.

2-3 Clearly V D V.Xn�Xn1 ; : : : ;X2�X21 /. The map

Xi 7! T i WkŒX1; : : : ;Xn�! kŒT �

induces an isomorphism kŒV �! A1. [Hence t 7! .t; : : : ; tn/ is an isomorphism of affinevarieties A1! V .]

2-4 We use that the prime ideals are in one-to-one correspondence with the closed irre-ducible subsets Z of A2. For such a set, 0� dimZ � 2.

Case dimZ D 2. Then Z D A2, and the corresponding ideal is .0/.Case dimZ D 1. Then Z ¤ A2, and so I.Z/ contains a nonzero polynomial f .X;Y /.

If I.Z/¤ .f /, then dimZ D 0 by (2.25, 2.26). Hence I.Z/D .f /.Case dimZ D 0. Then Z is a point .a;b/ (see 2.24c), and so I.Z/D .X �a;Y �b/.

2-5 The statement Homk�algebras.A˝Q k;B ˝Q k/ ¤ ; can be interpreted as saying thata certain set of polynomials has a zero in k. If the polynomials have a common zero inC, then the ideal they generate in CŒX1; : : :� does not contain 1. A fortiori the ideal theygenerate in kŒX1; : : :� does not contain 1, and so the Nullstellensatz (2.6) implies that thepolynomials have a common zero in k.

245

246 A. SOLUTIONS TO THE EXERCISES

3-1 A map ˛WA1!A1 is continuous for the Zariski topology if the inverse images of finitesets are finite, whereas it is regular only if it is given by a polynomial P 2 kŒT �, so it is easyto give examples, e.g., any map ˛ such that ˛�1.point/ is finite but arbitrarily large.

3-2 The argument in the text shows that, for any f 2 S ,

f .a1; : : : ;an/D 0 H) f .aq1 ; : : : ;a

qn/D 0:

This implies that ' maps V into itself, and it is obviously regular because it is defined bypolynomials.

3-3 The image omits the points on the Y -axis except for the origin. The complement of theimage is not dense, and so it is not open, but any polynomial zero on it is also zero at .0;0/,and so it not closed.

3-5 No, because bothC1 and �1 map to .0;0/. The map on rings is

kŒx;y�! kŒT �; x 7! T 2�1; y 7! T .T 2�1/;

which is not surjective (T is not in the image).

4-1 Let f be regular on P1. Then f jU0 D P.X/ 2 kŒX�, where X is the regular function.a0Wa1/ 7! a1=a0WU0! k, and f jU1 DQ.Y / 2 kŒY �, where Y is .a0Wa1/ 7! a0=a1. OnU0 \U1, X and Y are reciprocal functions. Thus P.X/ and Q.1=X/ define the samefunction on U0\U1 D A1r f0g. This implies that they are equal in k.X/, and must bothbe constant.

4-2 Note that � .V;OV /DQ� .Vi ;OVi / — to give a regular function on

FVi is the same

as to give a regular function on each Vi (this is the “obvious” ringed space structure).Thus, if V is affine, it must equal Specm.

QAi /, where Ai D � .Vi ;OVi /, and so V DF

Specm.Ai / (use the description of the ideals in A�B on p13). Etc..

4-3 Let H be an algebraic subgroup of G. By definition, H is locally closed, i.e., open inits Zariski closure NH . Assume first that H is connected. Then NH is a connected algebraicgroup, and it is a disjoint union of the cosets of H . It follows that H D NH . In the generalcase, H is a finite disjoint union of its connected components; as one component is closed,they all are.

5-1 (b) The singular points are the common solutions to8<:4X3�2XY 2 D 0 H) X D 0 or Y 2 D 2X2

4Y 3�2X2Y D 0 H) Y D 0 or X2 D 2Y 2

X4CY 4�X2Y 2 D 0:

Thus, only .0;0/ is singular, and the variety is its own tangent cone.

5-2 Directly from the definition of the tangent space, we have that

Ta.V \H/� Ta.V /\Ta.H/.

AsdimTa.V \H/� dimV \H D dimV �1D dimTa.V /\Ta.H/;

we must have equalities everywhere, which proves that a is nonsingular on V \H . (Inparticular, it can’t lie on more than one irreducible component.)

247

The surface Y 2DX2CZ is smooth, but its intersection with theX -Y plane is singular.No, P needn’t be singular on V \H if H � TP .V / — for example, we could have

H � V or H could be the tangent line to a curve.

5-3 We can assume V and W to affine, say

I.V /D a� kŒX1; : : : ;Xm�

I.W /D b� kŒXmC1; : : : ;XmCn�:

If a D .f1; : : : ;fr/ and b D .g1; : : : ;gs/, then I.V �W / D .f1; : : : ;fr ;g1; : : : ;gs/. Thus,T.a;b/.V �W / is defined by the equations

.df1/a D 0; : : : ; .dfr/a D 0;.dg1/b D 0; : : : ; .dgs/b D 0;

which can obviously be identified with Ta.V /�Tb.W /.

5-4 Take C to be the union of the coordinate axes in An. (Of course, if you want C to beirreducible, then this is more difficult. . . )

5-5 A matrix A satisfies the equations

.I C "A/tr �J � .I C "A/D I

if and only ifAtr�J CJ �AD 0:

Such an A is of the form�M N

P Q

�with M;N;P;Q n�n-matrices satisfying

N trDN; P tr

D P; M trD�Q.

The dimension of the space of A’s is therefore

n.nC1/

2(for N )C

n.nC1/

2(for P )Cn2 (for M;Q)D 2n2Cn:

5-6 Let C be the curve Y 2 D X3, and consider the map A1! C , t 7! .t2; t3/. The cor-responding map on rings kŒX;Y �=.Y 2/! kŒT � is not an isomorphism, but the map on thegeometric tangent cones is an isomorphism.

5-7 The singular locus Vsing has codimension � 2 in V , and this implies that V is normal.[Idea of the proof: let f 2 k.V / be integral over kŒV �, f … kŒV �, f D g=h, g;h 2 kŒV �;for any P 2 V.h/rV.g/, OP is not integrally closed, and so P is singular.]

5-8 No! Let aD .X2Y /. Then V.a/ is the union of the X and Y axes, and IV.a/D .XY /.For aD .a;b/,

.dX2Y /a D 2ab.X �a/Ca2.Y �b/

.dXY /a D b.X �a/Ca.Y �b/.

If a¤ 0 and b D 0, then the equations

.dX2Y /a D a2Y D 0

.dXY /a D aY D 0

248 A. SOLUTIONS TO THE EXERCISES

have the same solutions.

6-1 Let P D .a W b W c/, and assume c ¤ 0. Then the tangent line at P D .acWbcW1/ is�

@F

@X

�P

XC

�@F

@Y

�P

Y �

��@F

@X

�P

�ac

�C

�@F

@Y

�P

�b

c

��Z D 0:

Now use that, because F is homogeneous,

F.a;b;c/D 0 H)

�@F

@X

�P

aC

�@F

@Y

�P

C

�@F

@Z

�P

c D 0.

(This just says that the tangent plane at .a;b;c/ to the affine cone F.X;Y;Z/ D 0 passesthrough the origin.) The point at1 is .0 W 1 W 0/, and the tangent line is Z D 0, the line at1. [The line at1 meets the cubic curve at only one point instead of the expected 3, andso the line at1 “touches” the curve, and the point at1 is a point of inflexion.]

6-2 The equation defining the conic must be irreducible (otherwise the conic is singular).After a linear change of variables, the equation will be of the form X2CY 2 D Z2 (thisis proved in calculus courses). The equation of the line in aX C bY D cZ, and the rest iseasy. [Note that this is a special case of Bezout’s theorem (6.34) because the multiplicity is2 in case (b).]

6-3 (a) The ring

kŒX;Y;Z�=.Y �X2;Z�X3/D kŒx;y;z�D kŒx�' kŒX�;

which is an integral domain. Therefore, .Y �X2;Z�X3/ is a radical ideal.(b) The polynomial F DZ�XY D .Z�X3/�X.Y �X2/ 2 I.V / and F � DZW �

XY . IfZW �XY D .Y W �X2/f C .ZW 2

�X3/g;

then, on equating terms of degree 2, we would find

ZW �XY D a.YW �X2/;

which is false.

6-4 Let P D .a0W : : : Wan/ and Q D .b0W : : : Wbn/ be two points of Pn, n � 2. The conditionthat the hyperplane LcW

PciXi D 0 pass through P and not through Q is thatP

aici D 0;Pbici ¤ 0:

The .nC1/-tuples .c0; : : : ; cn/ satisfying these conditions form a nonempty open subset ofthe hyperplane H W

PaiXi D 0 in AnC1. On applying this remark to the pairs .P0;Pi /, we

find that the .nC1/-tuples cD .c0; : : : ; cn/ such that P0 lies on the hyperplane Lc but notP1; : : : ;Pr form a nonempty open subset of H .

6-5 The subsetC D f.a W b W c/ j a¤ 0; b ¤ 0g[f.1 W 0 W 0/g

of P2 is not locally closed. Let P D .1 W 0 W 0/. If the set C were locally closed, then Pwould have an open neighbourhood U in P2 such that U \C is closed. When we look inU0, P becomes the origin, and

C \U0 D .A2r fX -axisg/[foriging.

249

The open neighbourhoods U of P are obtained by removing from A2 a finite number ofcurves not passing through P . It is not possible to do this in such a way that U \C is closedin U (U \C has dimension 2, and so it can’t be a proper closed subset of U ; we can’t haveU \C D U because any curve containing all nonzero points on X -axis also contains theorigin).

7-2 Define f .v/ D h.v;Q/ and g.w/ D h.P;w/, and let ' D h� .f ıpCg ı q/. Then'.v;Q/ D 0 D '.P;w/, and so the rigidity theorem (7.13) implies that ' is identicallyzero.

6-6 LetPcijXij D 0 be a hyperplane containing the image of the Segre map. We then haveP

cijaibj D 0

for all aD .a0; : : : ;am/ 2 kmC1 and bD .b0; : : : ;bn/ 2 knC1. In other words,

aCbt D 0

for all a 2 kmC1 and b 2 knC1, where C is the matrix .cij /. This equation shows thataC D 0 for all a, and this implies that C D 0.

8-2 For example, consider

.A1r f1g/! A1x 7!xn

! A1

for n > 1 an integer prime to the characteristic. The map is obviously quasi-finite, but it isnot finite because it corresponds to the map of k-algebras

X 7!XnWkŒX�! kŒX;.X �1/�1�

which is not finite (the elements 1=.X �1/i , i � 1, are linearly independent over kŒX�, andso also over kŒXn�).

8-3 Assume that V is separated, and consider two regular maps f;gWZ⇒W . We have toshow that the set on which f and g agree is closed inZ. The set where ' ıf and ' ıg agreeis closed in Z, and it contains the set where f and g agree. Replace Z with the set where' ıf and ' ıg agree. Let U be an open affine subset of V , and let Z0 D .' ıf /�1.U /D.' ıg/�1.U /. Then f .Z0/ and g.Z0/ are contained in '�1.U /, which is an open affinesubset of W , and is therefore separated. Hence, the subset of Z0 on which f and g agree isclosed. This proves the result.

[Note that the problem implies the following statement: if 'WW ! V is a finite regularmap and V is separated, then W is separated.]

8-4 Let V D An, and let W be the subvariety of An�A1 defined by the polynomialQniD1.X �Ti /D 0:

The fibre over .t1; : : : ; tn/ 2 An is the set of roots ofQ.X � ti /. Thus, Vn D An; Vn�1 is

the union of the linear subspaces defined by the equations

Ti D Tj ; 1� i;j � n; i ¤ j I

Vn�2 is the union of the linear subspaces defined by the equations

Ti D Tj D Tk; 1� i;j;k � n; i;j;k distinct,

250 A. SOLUTIONS TO THE EXERCISES

and so on.

10-1 Consider an orbit O D Gv. The map g 7! gvWG! O is regular, and so O containsan open subset U of NO (10.2). If u 2 U , then gu 2 gU , and gU is also a subset of Owhich is open in NO (because P 7! gP WV ! V is an isomorphism). Thus O , regarded asa topological subspace of NO , contains an open neighbourhood of each of its points, and somust be open in NO .

We have shown that O is locally closed in V , and so has the structure of a subvariety.From (5.18), we know that it contains at least one nonsingular point P . But then gP isnonsingular, and every point of O is of this form.

From set theory, it is clear that NO rO is a union of orbits. Since NO rO is a properclosed subset of NO , all of its subvarieties must have dimension < dim NO D dimO .

Let O be an orbit of lowest dimension. The last statement implies that O D NO .

10-2 An orbit of type (a) is closed, because it is defined by the equations

Tr.A/D�a; det.A/D b;

(as a subvariety of V ). It is of dimension 2, because the centralizer of�˛ 0

0 ˇ

�, ˛ ¤ ˇ, is��

� 0

0 �

��, which has dimension 2.

An orbit of type (b) is of dimension 2, but is not closed: it is defined by the equations

Tr.A/D�a; det.A/D b; A¤

�˛ 0

0 ˛

�; ˛ D root of X2CaXCb.

An orbit of type (c) is closed of dimension 0: it is defined by the equationAD�˛ 0

0 ˛

�.

An orbit of type (b) contains an orbit of type (c) in its closure.

10-3 Let � be a primitive d th root of 1. Then, for each i;j , 1 � i;j � d , the followingequations define lines on the surface�

X0C �iX1 D 0

X2C �jX3 D 0

�X0C �

iX2 D 0

X1C �jX3 D 0

�X0C �

iX3 D 0

X1C �jX2 D 0:

There are three sets of lines, each with d2 lines, for a total of 3d2 lines.

10-4 (a) Compare the proof of Theorem 10.9.(b) Use the transitivity, and apply Proposition 8.23.

12-1 LetH be a hyperplane in Pn intersecting V transversally. ThenH � Pn�1 and V \His again defined by a polynomial of degree ı. Continuing in this fashion, we find that

V \H1\ : : :\Hd

is isomorphic to a subset of P1 defined by a polynomial of degree ı.

12-2 We may suppose that X is not a factor of Fm, and then look only at the affine piece ofthe blow-up, � WA2! A2, .x;y/ 7! .x;xy/. Then ��1.C r .0;0//is given by equations

X ¤ 0; F.X;XY /D 0:

251

ButF.X;XY /DXm.

Q.ai �biY /

ri /CXmC1FmC1.X;Y /C�� � ;

and so ��1.C r .0;0// is also given by equations

X ¤ 0;Q.ai �biY /

ri CXFmC1.X;Y /C�� � D 0:

To find its closure, drop the condition X ¤ 0. It is now clear that the closure intersects��1.0;0/ (the Y -axis) at the s points Y D ai=bi .

12-3 We have to find the dimension of kŒX;Y �.X;Y /=.Y 2 �Xr ;Y 2 �Xs/. In this ring,Xr D Xs , and so Xs.Xr�s � 1/ D 0. As Xr�s � 1 is a unit in the ring, this implies thatXs D 0, and it follows that Y 2 D 0. Thus .Y 2�Xr ;Y 2�Xs/� .Y 2;Xs/, and in fact thetwo ideals are equal in kŒX;Y �.X;Y /. It is now clear that the dimension is 2s.

12-4 Note thatkŒV �D kŒT 2;T 3�D

nPaiT

ij ai D 0

o:

For each a 2 k, define an effective divisor Da on V as follows:Da has local equation 1�a2T 2 on the set where 1CaT ¤ 0;Da has local equation 1�a3T 3 on the set where 1CaT CaT 2 ¤ 0.

The equations

.1�aT /.1CaT /D 1�a2T 2; .1�aT /.1CaT Ca2T 2/D 1�a3T 3

show that the two divisors agree on the overlap where

.1CaT /.1CaT CaT 2/¤ 0:

For a¤ 0, Da is not principal, essentially because

gcd.1�a2T 2;1�a3T 3/D .1�aT / … kŒT 2;T 3�

— if Da were principal, it would be a divisor of a regular function on V , and that regularfunction would have to be 1�aT , but this is not allowed.

In fact, one can show that Pic.V /� k. Let V 0 D V r f.0;0/g, and write P.�/ for theprincipal divisors on �. Then Div.V 0/CP.V /D Div.V /, and so

Div.V /=P.V /' Div.V 0/=Div.V 0/\P.V /' P.V 0/=P.V 0/\P.V /' k:

APPENDIX BAnnotated Bibliography

Apart from Hartshorne 1977, among the books listed below, I especially recommend Sha-farevich 1994 — it is very easy to read, and is generally more elementary than these notes,but covers more ground (being much longer).

Commutative AlgebraAtiyah, M.F and MacDonald, I.G., Introduction to Commutative Algebra, Addison-Wesley

1969. This is the most useful short text. It extracts the essence of a good part of Bourbaki1961–83.

Bourbaki, N., Algebre Commutative, Chap. 1–7, Hermann, 1961–65; Chap 8–9, Masson,1983. Very clearly written, but it is a reference book, not a text book.

Eisenbud, D., Commutative Algebra, Springer, 1995. The emphasis is on motivation.Matsumura, H., Commutative Ring Theory, Cambridge 1986. This is the most useful medium-

length text (but read Atiyah and MacDonald or Reid first).Nagata, M., Local Rings, Wiley, 1962. Contains much important material, but it is concise to

the point of being almost unreadable.Reid, M., Undergraduate Commutative Algebra, Cambridge 1995. According to the author, it

covers roughly the same material as Chapters 1–8 of Atiyah and MacDonald 1969, but ischeaper, has more pictures, and is considerably more opinionated. (However, Chapters 10and 11 of Atiyah and MacDonald 1969 contain crucial material.)

Serre: Algebre Locale, Multiplicites, Lecture Notes in Math. 11, Springer, 1957/58 (thirdedition 1975).

Zariski, O., and Samuel, P., Commutative Algebra, Vol. I 1958, Vol II 1960, van Nostrand.Very detailed and well organized.

Elementary Algebraic GeometryAbhyankar, S., Algebraic Geometry for Scientists and Engineers, AMS, 1990. Mainly curves,

from a very explicit and down-to-earth point of view.Reid, M., Undergraduate Algebraic Geometry. A brief, elementary introduction. The fi-

nal chapter contains an interesting, but idiosyncratic, account of algebraic geometry in thetwentieth century.

Smith, Karen E.; Kahanpaa, Lauri; Kekalainen, Pekka; Traves, William. An invitation to alge-braic geometry. Universitext. Springer-Verlag, New York, 2000. An introductory overviewwith few proofs but many pictures.

Computational Algebraic Geometry

253

254 B. ANNOTATED BIBLIOGRAPHY

Cox, D., Little, J., O’Shea, D., Ideals, Varieties, and Algorithms, Springer, 1992. This givesan algorithmic approach to algebraic geometry, which makes everything very down-to-earthand computational, but the cost is that the book doesn’t get very far in 500pp.

Subvarieties of Projective SpaceHarris, Joe: Algebraic Geometry: A first course, Springer, 1992. The emphasis is on exam-

ples.Musili, C. Algebraic geometry for beginners. Texts and Readings in Mathematics, 20. Hin-

dustan Book Agency, New Delhi, 2001.Shafarevich, I., Basic Algebraic Geometry, Book 1, Springer, 1994. Very easy to read.Algebraic Geometry over the Complex NumbersGriffiths, P., and Harris, J., Principles of Algebraic Geometry, Wiley, 1978. A comprehensive

study of subvarieties of complex projective space using heavily analytic methods.Mumford, D., Algebraic Geometry I: Complex Projective Varieties. The approach is mainly

algebraic, but the complex topology is exploited at crucial points.Shafarevich, I., Basic Algebraic Geometry, Book 3, Springer, 1994.Abstract Algebraic VarietiesDieudonne, J., Cours de Geometrie Algebrique, 2, PUF, 1974. A brief introduction to abstract

algebraic varieties over algebraically closed fields.Kempf, G., Algebraic Varieties, Cambridge, 1993. Similar approach to these notes, but is

more concisely written, and includes two sections on the cohomology of coherent sheaves.Kunz, E., Introduction to Commutative Algebra and Algebraic Geometry, Birkhauser, 1985.

Similar approach to these notes, but includes more commutative algebra and has a longchapter discussing how many equations it takes to describe an algebraic variety.

Mumford, D. Introduction to Algebraic Geometry, Harvard notes, 1966. Notes of a course.Apart from the original treatise (Grothendieck and Dieudonne 1960–67), this was the firstplace one could learn the new approach to algebraic geometry. The first chapter is onvarieties, and last two on schemes.

Mumford, David: The Red Book of Varieties and Schemes, Lecture Notes in Math. 1358,Springer, 1999. Reprint of Mumford 1966.

SchemesEisenbud, D., and Harris, J., Schemes: the language of modern algebraic geometry, Wadsworth,

1992. A brief elementary introduction to scheme theory.Grothendieck, A., and Dieudonne, J., Elements de Geometrie Algebrique. Publ. Math. IHES

1960–1967. This was intended to cover everything in algebraic geometry in 13 massivebooks, that is, it was supposed to do for algebraic geometry what Euclid’s “Elements” didfor geometry. Unlike the earlier Elements, it was abandoned after 4 books. It is an extremelyuseful reference.

Hartshorne, R., Algebraic Geometry, Springer 1977. Chapters II and III give an excellentaccount of scheme theory and cohomology, so good in fact, that no one seems willing towrite a competitor. The first chapter on varieties is very sketchy.

Iitaka, S. Algebraic Geometry: an introduction to birational geometry of algebraic varieties,Springer, 1982. Not as well-written as Hartshorne 1977, but it is more elementary, and itcovers some topics that Hartshorne doesn’t.

Shafarevich, I., Basic Algebraic Geometry, Book 2, Springer, 1994. A brief introduction toschemes and abstract varieties.

HistoryDieudonne, J., History of Algebraic Geometry, Wadsworth, 1985.Of Historical Interest

255

Hodge, W., and Pedoe, D., Methods of Algebraic Geometry, Cambridge, 1947–54.Lang, S., Introduction to Algebraic Geometry, Interscience, 1958. An introduction to Weil

1946.Weil, A., Foundations of Algebraic Geometry, AMS, 1946; Revised edition 1962. This is

where Weil laid the foundations for his work on abelian varieties and jacobian varietiesover arbitrary fields, and his proof of the analogue of the Riemann hypothesis for curvesand abelian varieties. Unfortunately, not only does its language differ from the currentlanguage of algebraic geometry, but it is incompatible with it.

Index

actioncontinuous, 224, 235of a group on a vector space, 223regular, 234

affine algebra, 186algebra

finite, 11finitely generated, 11

algebraic group, 81algebraic space, 187

in the sense of Artin, 216axiom

separation, 73axis

of a pencil, 239

basic open subset, 48Bezout’s Theorem, 200birationally equivalent, 86

category, 28Chow group, 200codimension, 155complete intersection

ideal-theoretic, 160local, 161set-theoretic, 160

complex topology, 215cone

affine over a set, 117content of a polynomial, 17continuous

descent system, 225curve

elliptic, 39, 116, 120, 189, 207, 212cusp, 93cycle

algebraic, 199

degreeof a hypersurface, 134of a map, 172, 198of a point, 192of a projective variety, 136

total, 18derivation, 108descent datum, 225

effective, 225descent system, 224Dickson’s Lemma, 34differential, 95dimension, 85

Krull, 52of a reducible set, 51of an irreducible set, 50pure, 51, 86

division algorithm, 32divisor, 195

effective, 195local equation for, 196locally principal, 196positive, 195prime, 195principal, 196restriction of, 196support of, 195

dual projective space, 239dual variety, 240

elementintegral over a ring, 19irreducible, 16

equivalence of categories, 29extension

of base field, 187of scalars, 187, 188of the base field, 188

fibregeneric, 229of a map, 147

fieldfixed, 219

field of rational functions, 50, 85form

leading, 93Frobenius map, 65

257

258 INDEX

functionrational, 59regular, 47, 57, 72

functor, 29contravariant, 29essentially surjective, 29fully faithful, 29

generate, 11germ

of a function, 56graph

of a regular map, 82Groebner basis, see standard basisgroup

symplectic, 113

homogeneous, 122homomorphism

finite, 11of algebras, 11of presheaves, 181of sheaves, 182

hypersurface, 51, 127hypersurface section, 127

ideal, 11generated by a subset, 11homogeneous, 116maximal, 12monomial, 33prime, 12radical, 44

immersion, 75closed, 75open, 75

integral closure, 19intersect properly, 197, 199irreducible components, 50isomorphic

locally, 111

leading coefficient, 32leading monomial, 32leading term, 32Lemma

Gauss’s, 16lemma

Nakayama’s, 14prime avoidance, 160Yoneda, 30Zariski’s, 42

linearly equivalent, 196local equation

for a divisor, 196

local ringregular, 15

local system of parameters, 105

manifoldcomplex, 71differentiable, 71topological, 71

mapbirational, 151dominant, 67, 87dominating, 67etale, 97, 112finite, 145flat, 198proper, 152quasi-finite, 147Segre, 129separable, 173Veronese, 126

model, 188module

of differential one-forms, 211monomial, 18Morita equivalent, 223morphism

of affine algebraic varieties, 60of functors, 30of locally ringed spaces, 182of ringed spaces, 60, 182

multidegree, 32multiplicity

of a point, 93

neighbourhoodetale, 106

nilpotent, 44node, 93nondegenerate quadric, 177nonsingular, 192

orderinggrevlex, 31lex, 31

ordinary double point, 240

pencil, 239Lefschetz, 239

pencil of lines, 178perfect closure, 220Picard group, 196, 205Picard variety, 208point

multiple, 95nonsingular, 91, 95

Index 259

ordinary multiple, 93rational over a field, 191singular, 95smooth, 91, 95with coordinates in a field, 191with coordinates in a ring, 87

polynomialHilbert, 135homogeneous, 115primitive, 17

presheaf, 181prevariety, 187

algebraic, 71separated, 73

principal open subset, 48product

fibred, 84of algebraic varieties, 80of objects, 77tensor, 26

projection with centre, 129projectively normal, 195

quasi-inverse, 29

radicalof an ideal, 43

rationally equivalent, 200regular field extension, 184regular map, 72regulus, 178resultant, 141Riemann-Roch Theorem, 212ring

coordinate, 47integrally closed, 20noetherian, 14normal, 104of dual numbers, 108reduced, 44

ringed space, 56, 182locally, 182

section of a sheaf, 56semisimple

group, 110Lie algebra, 111

set(projective) algebraic, 116constructible, 165

sheaf, 182coherent, 203invertible, 205locally free, 203of abelian groups, 182

of algebras, 55of k-algebras, 182of rings, 182support of, 204

singular locus, 92, 192specialization, 230splits

a descent system, 225stalk, 182standard basis, 35

minimal, 35reduced, 35

subring, 11subset

algebraic, 39multiplicative, 22

subspacelocally closed, 75

subvariety, 75closed, 65open affine, 72

tangent cone, 93, 111geometric, 93, 111, 112

tangent space, 91, 95, 101theorem

Bezout’s , 134Chinese Remainder, 12going-up, 147Hilbert basis, 34, 40Hilbert Nullstellensatz, 42Krull’s principal ideal, 158Lefschetz pencils, 240Lefschetz pencils exist, 240Noether normalization, 149Stein factorization, 180strong Hilbert Nullstellensatz, 44Zariski’s main, 151

topological spaceirreducible , 48noetherian, 47quasicompact, 47

topologyetale, 106Krull, 226Zariski, 41

variety, 187abelian, 81, 143affine algebraic, 60algebraic, 73complete, 137flag, 133Grassmann, 131

260 INDEX

normal, 105, 195projective, 115quasi-projective, 115rational, 86unirational, 86