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FYS3500 - spring 2020
Symmetry breaking in the weak interaction*
Alex ReadUniversity Of OsloDepartment of Physics
*Martin and Shaw, Nuclear and Particle Physics, 3rd Ed., Chapter 7 (Last update 21.04.2020 11:48)
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Introduction❖ Symmetries are extremely important in many branches of physics, including nuclear
and particle physics
❖ Conservation laws such as various charges, total angular momentum, parity, and C-parity allow us to distinguish between allowed and forbidden processes
❖ The breaking of symmetries is at least as interesting and revealing as the symmetries themselves
❖ e.g. breaking of gauge symmetry via the BEH mechanism
❖ e.g. the breaking of isospin symmetry by quark mass differences and electric charge differences
❖ Here we will how the (maximal) parity and C-parity violation in the (charged) weak interaction is restored by the product
❖ And how there are even small violations of CP-conservation
u, d
CP
2
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Parity violation in 1956❖ In early 1950’s two particles with (experimentally) the same spins (0),
masses and longish lifetimes decayed into 2 different states of parity:
❖ (not the -lepton) and
❖ Two different particles (remember, this is before the quark model)?
❖ Or parity not conserved in weak interaction?
❖ Question: How could we sort out the parity states?
❖ Lee and Yang (theorists) surveyed experimental results and observed that there was no real test of parity conservation in weak interactions.
τ → ππ τ θ → πππ
3
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Parity violation in 1957
❖ C.S. Wu et al tested parity conservation in polarized 60Co →60 Ni* + e− + νe
4
θπ − θ
Parity conservation: Γ(θ) = Γ(π − θ)C.S. Wu et al. Wolfgang Pauli: “I cannot believe God is a weak left-hander”.
r ⟶ − rp ⟶ − p
r × p ⟶ r × pL , S , J ⟶ L , S , J
P
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Polarized muon decays, C and P❖ Parity changes to ( ) but spins unaffected.
❖ C-parity inverts identity of all particles but angles, spins unaffected:
❖ If C-parity is conserved then and
❖ Unless , parity is clearly violated
❖ Experiment consistent with and
❖ violation of both C and P- conservation!
❖ What about product ?
❖ and
❖ conserved (e.g. equal lifetimes )
θ π − θ cos θ → − cos θ
C(μ+ → e+νeνμ) = μ− → e−νeνμ
ξ+ = ξ− Γ+ = Γ−
ξ± = 0
Γ+ = Γ− ξ− = − ξ+ = + 1
∴
CP
cos θ ↔ − cos θ ξ+(−1) ↔ ξ−(+1)
∴ CP ℏ/Γ+ = ℏ/Γ−
5
Γμ±(cos θ) =12
Γ± (1 −ξ±
3cos θ)
-1 -0.5 0 0.5 1cos
0
0.2
0.4
0.6
0.8
1
(cos)/
Muon decay+
-
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
CP conservation❖ Of course conserved in reactions that separately conserve C and P (EM, strong)
❖ Conserved in nearly all weak interactions
❖ Remember symmetry breaking is interesting!
❖ Lots of evidence of small CP-violation in hadronic weak interactions (first time in 1964 in system)
❖ Open research question whether there is similar CP-violation in leptonic sector (neutrino-mixing)
❖ Neither of these is thought to be large enough to explain the CP-violation in the early universe hypothesized by A. Sakharov to explain the matter-antimatter asymmetry of the current universe:
❖ Baryon number violation, C-symmetry violation, CP-symmetry violation, and interactions out of thermal equilibrium
K0 − K0
6
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Parity violation in neutral current interactions
❖ Remember, in any diagram with a we could just as easily write
❖ If the 4-momentum transfer is small compared to any effect will be tiny
❖ Challenging experiments, but even atomic physics is sensitive to the - atomic parity violation has been observed
γ γ/Z
mZ
Z
7
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Parity violation in e−e− → e−e−
8
e−
e−
e−
e−
⇐
e−
e−
e−
e−
⇒ P e−
e−
e−
e−
⇒
e−
e−
e−
e−
⇐
π
π
σR
σL
Parity violation: APV ≡σR − σL
σR + σL≠ 0 Question: What is the dominant
Feynman diagram?γ/Z
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Helicity and chirality in the weak interaction
❖ Eigenstates of chirality take part in the weak interaction
❖ Think of chirality as a kind of conserved charge
❖ For massless particles (the photon and approximately the neutrinos) helicity is equivalent to chirality, where helicity is the particle spin projected on the direction of motion, i.e.
❖ For massless particles helicity is Lorentz-invariant (i.e. conserved)
❖ Question: Why not so for massive particles?
❖ Helicity states of electron are +1 (right-handed), -1 (left-handed), i.e. spin-up, spin-down in direction of motion
❖ Question: What are the helicity states of the photon (massless vector boson)?
❖ Question: What are the helicity states of massive vector bosons like the ?
h ≡J ⋅ p
| J | | p |
W±, and Z
9
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
The neutrinos❖ We assume here that the neutrinos are massless
and so are either left-handed or right-handed helicity (chiral) states, independent of Lorentz frame.
❖ Weak interaction data can be understood by postulating that only and take part in weak interactions!
❖ In particular, violation of both while conserving is consistent with the above.
❖ The bosons couple to chiral doublets
and singlets e.g.
νLνR
νL νR
C and PCP
W± and Z
(νeLe−
L ), e−R and (e+
RνeR), e+
L
10
P
C
P
C
⇐νL
⇐νR⇐νL
⇐νR
(see "A Model of Leptons", by Steven Weinberg)
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
InteractionV − A
❖ represents a vector interaction (a vector like changes sign under parity)
❖ A represents an axial-vector interaction (an axial vector like does not change sign under parity)
❖ Both would conserve parity but interference terms in violate it
❖ The data are in precise agreement with the theory for charged weak interactions
V r or p
L ≡ r × p
|ℳ |2 ∝ |V |2 or |A |2
|ℳ |2 ∝ |V − A |2
V − A
11
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Mass and chirality❖ One of the consequences of is that “forbidden” helicity states of
massive fermions , e.g. , are suppressed by a factor
❖
❖ Excellent agreement between prediction and experiment when full calculation including the -values of the decays are taken into account.
❖ Question: What can we say about the degree of polarization of the muons in decays?
V − Af e−
R and e+L
(mfc2/Ef)2
Γ(π+ → e+ + νe)Γ(π+ → μ+ + νμ)
≈ (me
mπ /2mπ /2mμ
)2 = ( me
mμ )2
≈ 10−5
Q
π+ → μ+ + νμ
12
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Muon decays (again)
❖ Consider only maximum electron energy (as a qualitative approximation)
❖ Question: Is the red curve at the left consistent with the argument above? How?
13
-1 -0.5 0 0.5 1cos
0
0.2
0.4
0.6
0.8
1
(cos)/
Muon decay+
-
Γμ±(cos θ) =12
Γ± (1 −ξ±
3cos θ)
Part II Neutral hadron mixing and -violationCP
14
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Neutral kaon oscillations
❖ Two neutral kaons (e.g. produced in strong interactions)
❖ (S=+1) and (S=-1)
❖ Successive transitions allowed by second-order weak interaction. Lifetime is long enough that this must be taken into account.
❖ Question: Why not oscillations?
K0(498) = ds K0(498) = ds
|ΔS | = 2
n ↔ n
15
K0 → K0 → K0 → . . .S = + 1 S = − 1
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
-eigenstates of the weak interactionK0
❖ Assume that CP is conserved (must test this)
❖ Assume that neutral kaons are eigenstates of CP
❖
❖ Choose phases of C-parity such that
❖ Intrinsic parity is -1:
❖ satisfies all of the above
|K01,2 >
C P |K01,2 > ≡ (+1, − 1) |K0
1,2 >
C |K0, p > = − | K0, p > and C | K0, p > = − |K0, p >
P |K0, 0 > = − |K0, 0 > and P | K0, 0 > = − | K0, 0 >
|K01,2, 0 > ≡
1
2[ |K0, 0 > ± | K0, 0 > ]
16
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
CP of K0x → ππ
❖ Decay of spin-0 particle to 2 spin-0 ’s
❖ Orbital angular momentum of must be 0
❖ = +1
❖
❖
❖ for
❖ Identify
π0
π0π0
P = (Pπ)2(−1)L
C = (Cπ0)2 = + 1
C |π+π−, L > = (−1)L |π+π−, L > = + 1
∴ CP = + 1 K → ππ
K01 → π0π0, π+π−
17
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
CP of K0x → πππ
❖ Decay of spin-0 particle to 3 spin-0 ’s
❖ only possible for
❖
❖ C-parity of so
❖ for ( and by isospin symmetry)
❖ Identify
π0
L12 + L3 = 0 L12 = L3
P = (Pπ)3(−1)L12+L3 = − 1(−1)2L = − 1
π0 = + 1 (Cπ0)3 = + 1
∴ CP = − 1 K0x → π0π0π0 π+π−π0
K02 → π0π0π0, π+π−π0
18
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
K0S , K0
L
❖ Two states with almost equal mass 499 MeV/c2
❖ ,
❖ ,
❖ Tempting to identify ,
❖ 1964: CP violation observed!
❖ Question: How do we make a sample of ?
K0S → ππ τS ≈ 9 × 10−11 s
K0L → πππ τL ≈ 5 × 10−8 s
K01 = K0
S K02 = K0
L
B(K0L → π+π−) ≈ 10−3 ⟹
K0L
19
Stopped here 14.04.20
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Semi-leptonic decaysK0
❖ Study and
❖If CP is conserved then
❖ and
❖ Question: How we know which is which?
❖ So if CP is conserved we expect equal numbers of …
K0L → π−e+νe K0
L → π+e−νe
K0L = K2 =
1
2[ |K0 > + | K0 > ]
K0(ds) → π−e+νe K0(ds) → π+e−νe
π−e+νe and π+e−νe
20
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Asymmetry in semi-leptonic decaysK0L
21
Question: What is going on before ~10-10 s?
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Key question about CP-violation ( )CP❖ Is in the -system due to mixing or direct ?
❖ Mixing - the and are (non-orthogonal!) mixtures of CP-eigenstates ( ) and ( )
❖
❖ Direct - the and are pure CP-eigenstates and , but the latter decay to forbidden CP-states with a small
probability.
CP K0 CP
K0S K0
L K01
CP = + 1 K02 CP = − 1
|K0S , 0 > =
1
1 + |ϵ |2( |K0
1 , 0 > + ϵ |K02 , 0 > )
|K0L, 0 > =
1
1 + |ϵ |2(ϵ |K0
1 , 0 > + |K02 , 0 > )
K0S K0
L |K0S , 0 > = |K0
1 , 0 >|K0
L, 0 > = |K02 , 0 >
22
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Asymmetry in semi-leptonic decays IIK0L
❖Let’s calculate in the mixing scenario
❖
❖
❖
❖
❖ Also
❖
A =N+ − N−
N+ + N−
N+ ∝ | < K0 |K0L > |2 , N− ∝ | < K0 |K0
L > |2
|K0L > ∝ ϵ |K0
1 > + |K02 >
|K01 > ∝ ( |K0 > + | K0 > ), |K0
2 > ∝ ( |K0 > − | K0 > )
|K0L > ∝ (1 + ϵ) |K0 > − (1 − ϵ) | K0 >
|K0S > ∝ (1 + ϵ) |K0 > + (1 − ϵ) | K0 >
N+ ∝ (1 + ϵ)2, N− ∝ (1 − ϵ)2
23
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Asymmetry in semi-leptonic decays IIK0L
24
❖
❖ The observation of means that and consist of more matter ( ) than antimatter ( )!!
A =(1 + ϵ*)(1 + ϵ) − (1 − ϵ*)(1 − ϵ)(1 + ϵ*)(1 + ϵ) + (1 − ϵ*)(1 − ϵ)
=1 + |ϵ |2 + ϵ * +ϵ − 1 − |ϵ |2 + ϵ * +ϵ1 + |ϵ |2 + ϵ * +ϵ + 1 + |ϵ |2 − ϵ * −ϵ
=2(ϵ * +ϵ)
2(1 + |ϵ |2 )=
2ℜ(ϵ)1 + |ϵ |2 ≈ 2ℜ(ϵ)
2ℜ(ϵ) ≈ 2.3 × 10−3 K0L K0
SK0 K0
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
by mixingCP
❖We can define and
❖ If there is only mixing ( ) then
❖ Measured: and
❖ Difference is , consistent with 0, however, ….
❖ If direct ( ) is included (in detailed calculations) then and
❖ Combination of all available results gives and
❖ in the system is dominated by mixing, but there is also direct
η00 ≡< π0π0 |K0
L >< π0π0 |K0
S >η+− ≡
< π+π− |K0L >
< π+π− |K0S >
B(K02 → ππ) = 0 η00 = η+− = ϵ
η00 = (2.220 ± 0.011) × 10−3 η+− = (2.232 ± 0.011) × 10−3
η+− − η00 = (0.012 ± 0.026) × 10−3
CP B(K02 → ππ) ≠ 0 η+− = ϵ + ϵ′
η00 = ϵ − 2ϵ′
|ϵ | = (2.228 ± 0.011) × 10−3 |ϵ′ | = (3.69 ± 0.50) × 10−6
∴ CP K0 CP
25
|K0S , 0 > =
1
1 + |ϵ |2( |K0
1 , 0 > + ϵ |K02 , 0 > )
|K0L, 0 > =
1
1 + |ϵ |2(ϵ |K0
1 , 0 > + |K02 , 0 > )
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Flavor oscillations ( )K0 ↔ K0
❖ Let’s neglect for a minute…
❖ The lifetime of the -quark is long enough that we have to consider second-order weak interactions, such as
❖
❖ We can produce a pure state of in a strong interaction
❖ What happens as the propagates?
❖ Mathematics comparable to neutrino-flavor oscillations!
CP
s
K0(ds)
K0
26
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Flavor oscillations ( )K0 ↔ K0
❖ The initial strong state ( ) is (approximately, due to ) a mixture of weak eigenstates
❖ If then only the fact that changes the strangeness of the initial state
❖ In general we have
❖ where
❖ We decompose the and into the and components:
❖ , where and
t = 0 CP|K0, 0 > = ( |K0
S , 0 > + |K0L, 0 > )/ 2
m(K0L) ≡ mL = m(K0
s ) ≡ mS τ(K0S) ≪ τ(K0
L)
A(t) = (as(t) |K0S , 0 > + aL(t) |K0
L, 0 > )/ 2
aα(t) ≡ e−imαc2t/ℏe−Γαt/(2ℏ)
|K0S > |K0
L > |K0 > | K0 >
|A(t) > ≡ A0(t) |K0, 0 > + A0(t) | K0, 0 > A0(t) ≡ (aS(t) + aL(t))/2A0(t) ≡ (aS(t) − aL(t))/2
27
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Flavor oscillations ( )K0 ↔ K0
❖ (copied) , where and
❖
❖
❖ where
❖ Repeating much of the work, one can show that and
❖ This is not quite true if
|A(t) > ≡ A0(t) |K0, 0 > + A0(t) | K0, 0 >A0(t) ≡ (aS(t) + aL(t))/2 A0(t) ≡ (aS(t) − aL(t))/2
I(K0 → K0) = | < K0 |A(t) > |2 = |A0(t) |2 = . . .= [e−ΓSt/ℏ + e−ΓLt/ℏ + 2e−(ΓS+ΓL)t/ℏ cos(Δmc2t/ℏ)]/4
I(K0 → K0) = | < K0 |A(t) > |2 = | A0(t) |2 = . . .= [e−ΓSt/ℏ + e−ΓLt/ℏ − 2e−(ΓS+ΓL)t/ℏ cos(Δmc2t/ℏ)]/4
Δm ≡ |mS − mL |
I(K0 → K0) = I(K0 → K0)I(K0 → K0) = I(K0 → K0)
CP!
28
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Flavor oscillations ( )K0 ↔ K0
❖
❖
❖
❖ A fit to the data allows us to extract the and decay rates (lifetimes) and most importantly
❖ Question: Does everybody remember how to separate and decays?
I(K0 → K0) = [e−ΓSt/ℏ + e−ΓLt/ℏ + 2e−(ΓS+ΓL)t/ℏ cos(Δmc2t/ℏ)]/4
I(K0 → K0) = [e−ΓLt/ℏ + e−ΓSt/ℏ − 2e−(ΓS+ΓL)t/ℏ cos(Δmc2t/ℏ)]/4
αK(t) =I(K0 → K0) + I(K0 → K0) − I(K0 → K0) − I(K0 → K0)I(K0 → K0) + I(K0 → K0) + I(K0 → K0) + I(K0 → K0)
= . . .
=2e−(ΓS+ΓL)t/(2ℏ) cos(Δmc2t/ℏ)
e−ΓSt/ℏ + e−ΓLt/ℏ
K0S K0
LΔm = (3.483 ± 0.006) × 10−12 MeV/c2
K0 K0
29
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
CPT invariance❖ Relativistic quantum field theory predicts that is conserved, i.e., that
processes that also but conserve
❖ This has actually been tested at CERN (CPLEAR experiment)
❖ A fundamental prediction of CPT-invariance is that masses of particles and anti-particles should be identical, i.e.
❖ One can show that the measured is consistent with to better than 1 in 1018!
❖ are only tested to 1 part in 108-109
❖ Many tests of CPT-invariance - so far no exceptions
CPTCP T CPT
me+ = me−, mp = mp, mK0 = mK0, etc.
ΔmmK0 = mK0
me+ = me− and mp = mp
30
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
and -hadron decaysCP b
❖ Some similarity to , but direct- is much larger
❖ in mixing, direct, and interference
❖ Observable in charged -decays
❖ Question: Why isn’t in mixing not seen with charged- decays?
K0 − K0 CP
CP
B
CPB
31
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Direct in -decaysCP B❖ CP conserved:
❖CP-violation:
❖ e.g.
❖ Example in charged sector:
❖ Question: What are we comparing in this ?
Γ(A → f ) = Γ(A → f )
ACP ≡Γ(A → f ) − Γ(A → f )Γ(A → f ) + Γ(A → f )
≠ 0
ACP(B0 → K+π−) = − 0.082 ± 0.006
ACP(B+ → K+η) = − 0.37 ± 0.08
ACP
32
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
oscillations in a nutshellB0 − B0
❖ but (where heavy, light)
❖
❖ occurs when
❖ We still get flavor oscillations just like and can determine
❖ By the way, oscillations are now also observed!
τ(K0S) ≪ τ(K0
L) τ(B0H) ≈ τ(B0
L) H, L =
|B0L > = [ |B0 > + ξ | B0 > ]/ 2
|B0H > = [ |B0 > − ξ | B0 > ]/ 2
ξ ≈ e−2iβ
CP |ξ | ≠ 1
K0 − K0
mH − mL = (3.337 ± 0.033) × 10−10 MeV/c2
D0(cu) ↔ D0(cu)
33
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
in interference in a nutshellCP❖ If then the amplitude has two terms
❖ Since the two amplitudes can interfere and give us in interference
❖ This is observed in experiments that can measure time-dependent
asymmetry
❖ (BaBar-PEP II and Belle-Tristian II), (Tevatron), and (LHC)
❖ Question: How can we tag a or if both can decay to ?
❖ Under the interference hypothesis
Γ(B0 → f ) ≠ 0 and Γ(B0 → f ) ≠ 0ℳ(B0 → B0 → f ) and ℳ(B0 → B0 → f )
I ∝ ℳ2 CP
αfCP(t) ≡I (B0(t) → f) − I (B0(t) → f)I (B0(t) → f) + I (B0(t) → f)
e+e− pp pp
B0 B0 f
αfCP(t) = − ηf sin(2β)sin(Δmc2t/ℏ)
34
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Observation of in interferenceCP
❖
❖
❖ Requires , , where is
a CP-eigenstate, and assumes there is no direct here
αfCP(t) = − ηf sin(2β)sin(Δmc2t/ℏ)
sin(2β) = 0.682 ± 0.019
Δm ≠ 0B0 → f and B0 → f f
CP
35
f = J/Ψ + K0S (CP = − 1) f = J/Ψ + K0
L (CP = + 1)
Belle experiment at KEK
?!
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
and the CKM matrixCP
❖
Recall that
❖ may be complex.
❖ It can be shown (a fun project) that real parameters can be reduced by 9 unitary conditions ( ) and 5 arbitrary quark phases to 3 real angles and a complex
phase, e.g.
❖ P.S. It is less work to show that for 2 generations there is no need of a complex phase.
❖
d′
s′
b′
= VCKM (dsb) ≡
Vud Vus Vub
Vcd Vcs Vcb
Vtd Vts Vtb(
dsb)
Vij
2 × 3 × 3 = 18V†V = I
d′
s′
b′
=1 0 00 cos β sin β0 −sin β cos β
cos α 0 e−iδ sin α0 1 0
−eiδ sin α 0 cos α
cos θ sin θ 0−sin θ cos θ 0
0 0 1 (dsb)
VCKM =cos θ cos α sin θ cos α sin αe−iδ
−sin θ cos β − cos θ sin α sin βeiδ cos θ cos β − sin θ sin α sin βeiδ cos α sin βsin θ sin β − cos θ sin α cos βeiδ −cos θ sin β − sin θ sin α cos βeiδ cos α cos β
36
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
and the CKM matrixCP❖ Time-reversal operator (M&S 1.23)
❖ Since not all there will be and by CPT therefore also .
❖ None of the CKM angles are predicted by theory.
❖ However, the prediction of the CKM matrix is that there can be and all such phenomena can be parametrized by a single phase !
❖ So far all experimental data support this…
❖ …apart from the need for a much larger in the early universe.
TΨ( x , t) = Ψ * ( x , − t)
Vij * = Vij TCP
CPδ
CP
37
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
and Wolfenstein parameterizationCP❖ The Wolfenstein parameterization is an approximation of that highlights
the size of -effects in different parts of the matrix.
❖
❖ We aren’t going to go into the details, but one can show that this is consistent with:
❖ is small in strange and charm sectors and dominated by mixing
❖ in bottom sector is relatively large and direct is important in decays to final states with no charm nor strange
❖ By the way, has now also been observed in charm decays!
VCKMCP
VWP =
1 − λ2/2 − λ4/8 λ Aλ3(ρ − iη)−λ + A2λ5 [1 − 2(ρ + iη)]/2 1 − λ2/2 − λ4(1 + 4A2)/8 Aλ2
Aλ3 [1 − (1 − λ2/2)(ρ + iη)] −Aλ2 + Aλ4 [1 − 2(ρ + iη)]/2 1 − A2λ4/2+ O(λ6)
CP
CP CPB
CP
38
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
and 3 generations of leptonsCP❖ Similar consideration of 3 neutrino
generations allows for in the lepton sector.
CP
39
(sorry about the paywall)Question: How did T2K identify the neutrino-type in their detector?
FYS3500 Spring 2020 Alex Read, U. Oslo, Dept. Physics
Lists of concepts
❖ Parity violation
❖ C-violation
❖ CP-conservation
❖ Helicity
❖ Chirality
40
❖ Right-handed
❖ Left-handed
❖
❖ V-A
❖ Polarization
ν
ν
l−L , l−
R
❖ oscillations
❖ Semi-leptonic decays
❖
❖ CP eigenstates
❖ CP violation ( )
❖ by mixing
❖ by interference
K0 − K0
K0
K0S , K0
L
CP
CP
CP
❖ Direct
❖ Flavor oscillations
❖ Flavor tagging
❖ CPT invariance
❖ CKM matrix
❖ Wolfenstein parameterization
❖ in lepton sector
CP
CP
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