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The chemistry of the The chemistry of the transition metalstransition metals
Chapter 22Chapter 22
22
Electron configurationsElectron configurations
• Let’s write the 3d metals’ and their Let’s write the 3d metals’ and their ions’ eions’ e-- configurations configurations
• Sc, V, Cr, Fe, Ni, Cu, ZnSc, V, Cr, Fe, Ni, Cu, Zn
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Atomic sizeAtomic size
• Atomic size decreases across Atomic size decreases across period & increases down a period & increases down a columncolumn
• Not a big change to the radii Not a big change to the radii across the rowacross the row– Due to eDue to e--’s being stable in ’s being stable in
outermost orbital (4s) while outermost orbital (4s) while adding to 3dadding to 3d
• But 3But 3rdrd row roughly same as 2 row roughly same as 2ndnd, , not largernot larger– Due to eDue to e--’s going into 4f ’s going into 4f – The f-subshell is ineffective The f-subshell is ineffective
at shielding outer eat shielding outer e--’s from ’s from nuclear chargenuclear charge• Outer eOuter e--’s held more ’s held more
tightly by nucleustightly by nucleus– Called Called lanthanide lanthanide
contractioncontraction
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Ionization energyIonization energy
• Increase across rowIncrease across row
• But increase smaller But increase smaller than for main-group than for main-group elementselements
• Also, 3Also, 3rdrd transition row transition row has higher ionization E has higher ionization E (generally) than first 2 (generally) than first 2 rowsrows– Runs counter to main-Runs counter to main-
group elementsgroup elements• Due to outer eDue to outer e--’s being ’s being
held more tightlyheld more tightly
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Electronegativity Electronegativity
• Increase across row, same as main-groupIncrease across row, same as main-group
• However, increase going down a groupHowever, increase going down a group– Conversely, main-group decrease going down a Conversely, main-group decrease going down a
groupgroup
• 11stst & 2 & 2ndnd rows different, but 2 rows different, but 2ndnd & 3 & 3rdrd same same– Due to small change in atomic size going down Due to small change in atomic size going down
group w/large increase in nuclear chargegroup w/large increase in nuclear charge
• Au = 2.4 !Au = 2.4 !
• AuAu-- found to exist! found to exist!
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Oxidation statesOxidation states
• VariableVariable– Up to +8 in Os & RuUp to +8 in Os & Ru
• Re has widest range: -3 Re has widest range: -3 +7 ! +7 !
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Coordination compoundsCoordination compounds
• Can form Can form complex ionscomplex ions– Ion containing central metal ion bound to Ion containing central metal ion bound to
one or more one or more ligandsligands•Lewis base (or eLewis base (or e-- donor) that forms bond donor) that forms bond
w/metalw/metal
• When complex ion combines When complex ion combines w/counter-ions (non-ligands) they w/counter-ions (non-ligands) they yield a neutral compoundyield a neutral compound– Coordination compoundCoordination compound
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Its historyIts history
• Alfred WernerAlfred Werner
• Central metal ion has 2 types of interactions:Central metal ion has 2 types of interactions:
• 1. 1. primary valenceprimary valence: oxidation state on : oxidation state on central metal atomcentral metal atom
• 2. 2. secondary valencesecondary valence: # of molecules/ions : # of molecules/ions bound to metal atom, called bound to metal atom, called coordination #coordination #..
• Ex: CoClEx: CoCl33 6NH 6NH33 has primary valence of 3 and has primary valence of 3 and coordination # of 6coordination # of 6
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More More
• Can think of metal-Can think of metal-ligand complex as ligand complex as Lewis acid/base Lewis acid/base adductadduct– Since ligand Since ligand
donates edonates e- - pair to pair to empty orbital on empty orbital on metalmetal• Called Called coordinate coordinate
covalent bondcovalent bond
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More on ligandsMore on ligands
• Those that donate one eThose that donate one e-- pair = pair = monodentatemonodentate (why is it CO and not OC?) (why is it CO and not OC?)
• Those that donate 2 = Those that donate 2 = bidentatebidentate• More than 2 = More than 2 = polydentatepolydentate
• Latter two called Latter two called chelateschelates• Coordinating ligand = Coordinating ligand = chelating agentchelating agent
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Naming coordination Naming coordination compoundscompounds
1.1. Name ligandsName ligands– Neutral ligands named as molecules Neutral ligands named as molecules
except for Hexcept for H22O (aqua), NHO (aqua), NH33 (ammine), (ammine), and CO (carbonyl)and CO (carbonyl)
– Anionic ligands have suffix changes:Anionic ligands have suffix changes:• -ide -ide -o -o fluoride fluoride fluoro fluoro• -ate -ate -ato -ato sulfate sulfate sulfato sulfato• -ite -ite -ito -ito nitrite nitrite nitrito nitrito
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Naming coordination Naming coordination compoundscompounds
2.2. List names of ligands in alphabetical List names of ligands in alphabetical order before name of metal cationorder before name of metal cation
– For example: ammine comes before bromoFor example: ammine comes before bromo
3.3. Use prefix to indicate # of ligandsUse prefix to indicate # of ligands– 2 2 di di diamminediammine– 3 3 tri tri triiodotriiodo– 4 4 tetra tetra tetranitritotetranitrito– 5 5 penta penta– 6 6 hexa hexa
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Naming coordination Naming coordination compoundscompounds
– If the ligand name already has a number If the ligand name already has a number prefix, put () around ligandprefix, put () around ligand
– 2 2 bis bis bis(ethylenediamine)bis(ethylenediamine)– 3 3 tris tris tris(edta)tris(edta)– 4 4 tetrakis tetrakis– Prefixes don’t affect order in which Prefixes don’t affect order in which
ligands listedligands listed
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Naming coordination Naming coordination compoundscompounds
4.4. Name metalName metal– When complex ion is When complex ion is cationcation, use name of , use name of
metal followed by oxidiation state metal followed by oxidiation state w/Roman numeralw/Roman numeral• PtPt2+2+ = platinum (II) = platinum (II)
– If complex ion If complex ion anionicanionic, drop ending of , drop ending of metalmetal• Add –ate followed by oxid. state w/Roman Add –ate followed by oxid. state w/Roman
numeralnumeral– PtPt2+2+ = platinate(II) = platinate(II)
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Naming coordination Naming coordination compoundscompounds5.5. Write entire name by listing ligands first then Write entire name by listing ligands first then
metalmetal– Chemical formula: Chemical formula:
• Symbol of metal first, then neutral molecules and anions Symbol of metal first, then neutral molecules and anions last (all one word!)last (all one word!)– Hexaamminecobalt(III) ion= [Co(NHHexaamminecobalt(III) ion= [Co(NH33))66]]3+3+
– Diamminetetrachloroplatinate(II) ion = [Pt(NHDiamminetetrachloroplatinate(II) ion = [Pt(NH33))22ClCl44]]2-2-
– If more than one anion or neutral molecule in ligand, list If more than one anion or neutral molecule in ligand, list in alphabetical order in alphabetical order based on chemical symbolbased on chemical symbol
• [Mn(CO)(NH[Mn(CO)(NH33))55]SO]SO4 4 is correctis correct• [Mn(NH[Mn(NH33))55(CO)]SO(CO)]SO44 is is incorrectincorrect
– SOSO4 4 is called a “counter-ion”is called a “counter-ion” There should be a space between the complex ion and the There should be a space between the complex ion and the
counter-ioncounter-ion
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Practice namingPractice naming
• [Cr(H[Cr(H22O)O)55Cl]ClCl]Cl22
• KK33[Fe(CN)[Fe(CN)66]]
• NaNa22[PtCl[PtCl44]]
• [Mn(CO)(NH[Mn(CO)(NH33))55]SO]SO44
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Practice writing chemical Practice writing chemical formulaeformulae
• Tetraaquaplatinum(II) Tetraaquaplatinum(II) hexachloroplatinate(IV)hexachloroplatinate(IV)
• Ammonium Ammonium diaquatetrabromovanadate(III)diaquatetrabromovanadate(III)
• Tris(ethylenediamine)cobalt(III) Tris(ethylenediamine)cobalt(III) trioxalatoferrate(III)trioxalatoferrate(III)
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Structure and isomerizationStructure and isomerization
• 3 categories3 categories1.1. Structural isomers: atoms connected in Structural isomers: atoms connected in
different waysdifferent ways1.1. Coordination isomersCoordination isomers2.2. Linkage isomersLinkage isomers
2.2. Geometric isomers: ligands have different Geometric isomers: ligands have different spatial arrangementspatial arrangement1.1. Cis-trans isomersCis-trans isomers2.2. Octahedral complex isomersOctahedral complex isomers
3.3. Optical isomers: nonsuperimposable mirror-Optical isomers: nonsuperimposable mirror-images (enantiomers)images (enantiomers)
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Structural isomerism: Structural isomerism: coordination isomerscoordination isomers
• Coordination isomersCoordination isomers– Coordination ligand exchanges places Coordination ligand exchanges places
w/uncoordinated counter-ionw/uncoordinated counter-ion
• Ex: [Co(NHEx: [Co(NH33))55Br]Cl vs. [Co(NHBr]Cl vs. [Co(NH33))55Cl]BrCl]Br
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Structural isomerism: linkage Structural isomerism: linkage isomersisomers
• Either one of atoms in NOEither one of atoms in NO22-- can bond can bond
to metalto metal– When O, nitrito: ONOWhen O, nitrito: ONO--
– When N, nitro: NOWhen N, nitro: NO22--
• Different color compounds (page Different color compounds (page 1089)1089)
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Geometric isomerism: cis-trans Geometric isomerism: cis-trans isomersisomers
• Occurs in sq-planar: MAOccurs in sq-planar: MA22BB22
• And octahedral complexes: MAAnd octahedral complexes: MA44BB22
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Geometric isomerism: Geometric isomerism: octahedral complex isomersoctahedral complex isomers
• MXMX33YY33
• Fac (facial) isomerFac (facial) isomer– Three identical ligands at corners of a Three identical ligands at corners of a
triangular triangular faceface of octahedron of octahedron
• Mer (meridian) isomerMer (meridian) isomer– Three identical ligands at corners of a Three identical ligands at corners of a
triangular triangular meridianmeridian (inside octahedron) (inside octahedron)
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Optical isomerismOptical isomerism
• Nonsuperimposable mirror-imagesNonsuperimposable mirror-images– EnantiomersEnantiomers
• Have chirality/chiral centerHave chirality/chiral center
• Rotation of plane-polarized light in Rotation of plane-polarized light in opposite directionsopposite directions
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Geometries Geometries
• Depend in part on coordination #Depend in part on coordination #
• Coordination #Coordination # ShapeShape ExampleExample
• 22 linear linear [Ag(NH[Ag(NH33))22]]++
• 44 dd88 sq planar sq planar [PdCl[PdCl44]]2-2-
• 44 dd1010 tetrahedral [Zn(NH tetrahedral [Zn(NH33))44]]2+2+
• 66 octahedral [Fe(H octahedral [Fe(H22O)O)66]]3+3+
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Bonding in coordination Bonding in coordination compoundscompounds
• Valence Bond Theory: hybridization Valence Bond Theory: hybridization of orbitals (CHEM&141)of orbitals (CHEM&141)
• Filled orbital on ligandFilled orbital on ligand
• Empty orbital on metal cation Empty orbital on metal cation – Lead to hybridized orbitalsLead to hybridized orbitals
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Hybridizations of complex Hybridizations of complex ionsions
Geometry Geometry HybridizationHybridization
• LinearLinear spsp
• TetrahedralTetrahedral spsp33
• Square planarSquare planar dspdsp22
• OctahedralOctahedral dd22spsp33
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Crystal Field TheoryCrystal Field Theory
• VB theory can’t explain color and VB theory can’t explain color and magnetism of coordination compoundsmagnetism of coordination compounds
• Basically, complex ions form due to Basically, complex ions form due to attractions between eattractions between e-- on ligands and on ligands and positive charge on metal ionpositive charge on metal ion– Yet, eYet, e-- on ligands repel e on ligands repel e-- in in unhybridized unhybridized metal metal
d-orbitalsd-orbitals
• Crystal Field Theory (CFT) focuses on Crystal Field Theory (CFT) focuses on these repulsionsthese repulsions
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Ligands attack on x, y, z Ligands attack on x, y, z axesaxes
• Notice how ligands interact most strongly with top two orbitals’ lobesNotice how ligands interact most strongly with top two orbitals’ lobes– Greater interactionsGreater interactions
• Higher repulsionsHigher repulsions
• In below three, orbitals lie between axes & have nodes directly on axesIn below three, orbitals lie between axes & have nodes directly on axes– Less interactionsLess interactions
• Lower repulsionsLower repulsions
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More…More…
• D-orbitals end up being split into low- and D-orbitals end up being split into low- and high-E orbitalshigh-E orbitals– Based on spatial arrangement of ligandsBased on spatial arrangement of ligands
• High-E orbitals are top two (see previous figure)High-E orbitals are top two (see previous figure)• Low-E orbitals are bottomw three (see previous Low-E orbitals are bottomw three (see previous
figure)figure)
• Diff in E between split d-orbitalsDiff in E between split d-orbitals– Crystal field splitting ECrystal field splitting E– = = ∆∆
• Magnitude of ∆ depends on particular complex Magnitude of ∆ depends on particular complex (mostly its ligands)(mostly its ligands)
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Octahedral geometryOctahedral geometry
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Tetrahedral Tetrahedral
• Based on how ligands interact with Based on how ligands interact with orbital lobesorbital lobes
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Square planarSquare planar
• Again, based on how ligands overlap Again, based on how ligands overlap with orbital lobeswith orbital lobes
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Comparing all 3 ligand Comparing all 3 ligand geometriesgeometries
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Calculate Calculate ∆ (crystal field ∆ (crystal field splitting E)splitting E)
• Using EUsing Ephotonphoton = h = h = hc/ = hc/ = = ∆∆
• [Ti(H[Ti(H22O)O)66]]3+3+ has max abs @ 498 nm has max abs @ 498 nm
• What is the CFSE in kJ/mol?What is the CFSE in kJ/mol?
• Calculate it!Calculate it!
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Solution Solution
photon
34 8
9
-19 -19 -22
-22 23
hcE = h = =
m(6.626 10 J s)(3.00 10 )hc s = 498 10 m
3.99 10 J = 3.99 10 J/ion = 3.99 10 kJ/ion
kJ ions kJ3.99 10 6.022 10 240ion mol mol
3636
Magnitude of CFSEMagnitude of CFSE
• Depends largely on ligands involvedDepends largely on ligands involved– Spectroscopic studies of various ligands Spectroscopic studies of various ligands
attached to same metal attached to same metal •Yield Yield Spectrochemical seriesSpectrochemical series
– Arranged from ligands that result in Arranged from ligands that result in largest ∆ to smallestlargest ∆ to smallest
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Spectrochemical seriesSpectrochemical series
• CNCN-- > NO > NO22-- > en > NH > en > NH33 > (typically > (typically
strong-field ligands)strong-field ligands)
• HH22O > OHO > OH-- > F > F-- > Cl > Cl--> Br> Br--> I> I-- (typically weak-field ligands)(typically weak-field ligands)
• Large ∆ = strong-field ligandsLarge ∆ = strong-field ligands
• Small ∆ = weak-field ligandsSmall ∆ = weak-field ligands
3838
More More
• Also, as oxidation state increases, so Also, as oxidation state increases, so does ∆does ∆– Draws ligands closer to metal, increases Draws ligands closer to metal, increases
nodal repulsionsnodal repulsions
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Magnetic propertiesMagnetic properties
• Magnitude of Magnitude of ∆ ∆ determines d-orbital determines d-orbital occupancy and # of occupancy and # of unpaired eunpaired e--’s’s
• Large ∆ = strong-Large ∆ = strong-field ligands: field ligands: – Low-spin complexesLow-spin complexes
• Small ∆ = weak-field Small ∆ = weak-field ligands:ligands:– High-spin High-spin
complexescomplexes
4040
Magnetic propertiesMagnetic properties
• Low-spin complexes tend to be diamagneticLow-spin complexes tend to be diamagnetic• High-spin complexes tend to be paramagneticHigh-spin complexes tend to be paramagnetic
• dd11, d, d22, d, d33, d, d88, d, d99, and d, and d1010 do not rely on ligand splitting do not rely on ligand splitting strengthstrength
• Why?Why?
• Practice: Practice: • How many unpaired eHow many unpaired e--’s would one expect for ’s would one expect for
[FeCl[FeCl66]]3-3-??• How many unpaired eHow many unpaired e--’s would one expect for ’s would one expect for
[Co(CN)[Co(CN)66]]4-4-??
4141
Color of complex ionsColor of complex ions
• The color wheel: absorption of color The color wheel: absorption of color appears as complementary colorappears as complementary color
4242
Color of complex ionsColor of complex ions
• Color Color inin causes lower d-orbital e causes lower d-orbital e-- to to go up to higher d-orbital statego up to higher d-orbital state– Specific wavelength of light kicked outSpecific wavelength of light kicked out
•The complement of color absorbedThe complement of color absorbed
• Colorless complexes are either dColorless complexes are either d00 or or dd1010
– Don’t have d-orbital eDon’t have d-orbital e--’s to move up’s to move up
4343
Problem Problem
• Two ligands form complexes with Two ligands form complexes with same metal ion. The first ligand, A, same metal ion. The first ligand, A, complexes a red soln, while the complexes a red soln, while the second ligand, B, complexes a yellow second ligand, B, complexes a yellow soln. soln.
• Which ligand produces the larger Which ligand produces the larger ∆?∆?
