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Lecture 14 – Neutral currents and electroweak unification
● Neutral currents ● Electroweak unification● Number of neutrinos and fermion generation● The Standard Model● The Higgs boson
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Basic diagrams for weak neutral currents
u c
Same quark flavour: u,d,s,c,b,t
Flavour changing: forbidden
u
c
Same quark flavour: u,d,s,c,b,t
Flavour changing: forbidden
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Using the mixed states', '
' cos sin ' sin cos
Discussed in lecture 13 that the weak force "saw" mixed states and this led to cross-generation interactions.
; (13.02)instead of physical states and .(S
C C C C
d s
d d s s d sd s
2 21 ' ' cos sin cos sin cos sin
imple two-doublet approximation.)Show that it doesn't matter whether we use the physical or Cabibbo-rotated states.
Contributions to amplitude:
C C C C C CM d d d s d s dd ss ds sd
2 22
1 2
2 2 2 2
sin cos
' ' sin cos sin cos sin cos sin cos
' ' ' '
cos sin sin cos sin cos
(14.01)
(14.02)
(14.03)
C C
C C C C C C C C
C C C C C C
M s s d s d s dd ss ds sd
M M M
d d s s
dd ss ds sd dd ss ds sd
sin cos
(14.04)Neutral currents don't change flavour.
C C
dd ss
+ +=
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Question0Draw Feynman diagrams for and
What are the decay rates for these processes ?Are these results in agreement with the assertion that flavour changing neutral currents are suppressed ?
e LK e K e e
0
053 10 .
has not been observed.
Best limits on decay rates are:
L
L
e
K e e
K e e
K e
K-us
e-
Z0
dK0
forb
idde
n
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ss
,Z0
Neutral currents
Evidence for charged current interactions via is readily available at low energies. In 1938 Klein proposed a heavy charged particle was responsible for weak processes. It was hard toavoid observi
W
0
.
.
,
ng their influence:
eg nuclear -decay and decays: +
Until 1973 all weak interactions could be understood with the
Evidence for the neutral partner of the the was mo
en p e
W
W Z
0 0
0
re difficult to obtain:
(1) There's no flavour changing allowed eg is forbidden as a -process.
(2) Any decays which would mediated by the heavy would also be mediated by thephoton and t
LK e e Z
Z
he weak contribution would be unobservable.
Eg ss
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Rare decays0The decay can take place but is predicted to be incredibly
rare since higher orders/internal loops are needed.
The search for rare decays is useful for (1) testing our theories to high precis
LK e e
ion(2) looking for evidence of "new physics".Eg supersymmetry predicts many new heavy particles which can also manifest themselves in loops at low energy and which can thus change decay rates.
s
d
Wu
u
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0
0
Bubble chamber experiment at CERN, 1973.
Look for interaction:
Obs! We used neutrino to find about that the exists.
Later in this lecture we'll use the to tell us how many neutrinos ex
e e
Z
Z
ist.
e-
First evidence for neutral current weak processes
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Electroweak theory0
0,
The existence of the was not a great surprise. Electroweak theory predicted it would exist
(and the masses). The is necessary to ensure that calculations for certain processes were not dive
Z
W Z Z
rgent.
Electroweak theory was developed by Glashow, Weinberg and Salam (Nobel prize 1979).
It unifies the the weak and electromagnetic forces in a single theoretical framework.The details are very complex but it the achievement is on the same footing as theunification of the electric and magnetic forces into a single electromagnetic forcewith the Maxwell equations and special relativity.
What concerns us are the predictions and how they were confirmed by experiment.
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2 26400 GeVWM
Electroweak unification
e
0, , .
Electroweak theory states that the weak and electromagnetic forces look different at low
energies due to the masses of and At high energies combined electroweak force.From lecture 13:
Z W
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Electroweak theory predictions
2
0
12
0
4
sin cos2 2 2
Unification condition links the electromagnetic and weak couplings:
= =electromagnetic coupling constant (1.24)
(14.05) neutral current coupling (14.06)
Weak mixi
W W Z W Z
e
e g g g
02
3 0
ng angle cos (14.07)
Anomaly condition:
; sum over all leptons and quarks (14.08)
lepton charge , quark charge Also, each family individually satis
WW W
Z
aa
a
MM
Q Q a
Q Q
2 13 - 3 03 3
fies the anomaly condition.Eg first generation of lepton and quarks
(14.09)
ee u dQ Q Q Q e e e
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2 22
2
2 22 2
5 2
2
22
2sin 2 sin
1.166 10
For low energy charged current interactions, recall:
(2.39)
From (14.05) (14.10)
Fermi constant= GeV (2.37)
Using (14.07)
W WFW
W F
W WW F W
F
Z
g gG MM G
g MG
G
M
2 2
2 20 2
2
222
2 2
2 sin cos
22
sin
sin
(14.11)
Low energy weak interaction: (14.12) (14.13)
(14.14)
measure from rates of low energy charged and neutral curr
F W W
Z Z ZZ
Z Z
WZ ZW
F W Z
W
G
G g gZ MM G
MG gG g M
2
0
sin 0.227 0.014
78.3 2.4 89.0 2.0
ent processes.
Measurement (1981): (14.15)
Predicted and masses from the couplings. GeV ; GeV (14.16)
Consistent with masses measured i
W
W Z
W ZM M
n 1983 (UA1, UA2 experiments). Nobel prize (1983, Carlo Rubbia and Simon Van der Meer).
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A small correction2sin 0.2315 0.0001 (14.17)
77.5 0.03 88.41 0.04
80.4 0.02 91.188 0.002
Current measurement: from (14.10) and (14.11) GeV ; GeV (14.18)
Current direct mass measurements: GeV ; Ge
W
W Z
W Z
M M
M M
2 2
2 22 2
V (14.19)
We were wrong to use (2.39) and (14.12)
This neglected loop contributions as below. More precise calculations take these into account and obtain good agreement with t
WF Z Z
W Z
gG G gM M
†
†
he directly measured
masses
Hidden in this is an interesting principle - that the measured masses of particles are sensitive to the existence and properties (eg mass) of other particles.
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Strategy for directly observing Z0
0(1) Demonstrate how to measure the mass of the .
(2) Demonstrate how the same experiments also allow us to answer an interesting question.
We know there are three lepton doublets. Each doublet has on
Z
200
e charged lepton with massand a (just about) massless neutrino . Has nature only given us 3 families ?Are there more families i.e. heavier charged leptons (> GeV) that we can'tdirectly disco
ver at current colliders which are associated with light neutrinos in a doublet ?
Eg when we turn on the LHC is it likely we'll extend our table of leptons with a new
lepton pair: and YY
Lepton Charge (e) Mass (GeV)
e- -1 0.0005
e 0 0
-1 0.105
0 0
-1 1.8
0 0
Y- -1 > 200
Y 0 0?
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Measuring the mass and decays of a Z0
0
0
0
.
-interactions reminder.
Any process in which a photon is exchanged can also take place with a
In addition, the interacts with neutrinos.
Z
Z
Z
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Energy dependence
mostly
mostly
0 91.2 GeVZ
M
0
0
Consider annihilation reaction in centre-of-mass frame.
Can be mediated by photon or .
When is the photon contribution big
and the contribution small andvice versa ?
Photon contribution
e e
Z
Z
0
2
2
0
2 2
0
)
2
: (14.20)
contribution:
(for (14.21)
beam energy
mass of photon/ (14.22)
Z ZZ
CM
EZ
G E E M
E
E E Z
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LEP
0
Large Electron-Positron Collider at CERN, Geneva.Started 1989: 45 GeV + 45 GeV electrons and positrons.
Designed as a factory. Similar facility at SLAC, California: SLC. LEP was later upgraded to
Zhigher energies, eventually reaching 209 GeV
and almost finding (or finding depending on who you talk to) the Higgs boson.
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hadrons from LEP and other colliderse e
The Z0 resonance is what concerns us. What can we learn from it ?
LEP + SLD (at Z0)
Lower energy experiments
W W
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Resonances reminder
2
20
1
4
(4.11)m m
From lecture 4 Short-lived particles simply don’t have well-defined masses. Their masses follow a Breit-Wigner distribution
:decay from tedreconstruc Mass
770 MeV – ”nominal” mass
2
1 (4.12)
1 (nu) (MKS)
Consistent with uncertainty principle (1.27).
Γ Δm τ
Δmτ Δm c τ
E t
1 m E
:decay from mass Measured
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What an experiment observes
What is meant by ? What is ?Eg OPAL experiment at LEP.
Observe and count , eg number of hadronsevents.
Similarly could be observed andcounted - select events appropriate t
e e X X
e e
e e
, , .o the lepton species:
can't be observed in the detector.The neutrinos interact so weakly that they are never seen. We can still, however, work out that they were produced and count
e
e e
how many neutrino species exist!
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The Z0 resonance
01 25
0 02
22 2 2 2 2
1
2.495 0.0021 0.4 10
2.5
12
(4.12)
GeV (14.23)
GeV (14.24)
Consider any chosen observed final states,
(14.25)
Z
Z
Z
CM CM Z Z Z
m
m
s
e e XX
Z e e Z XMe e XE E M M
0 0
0 0
strength of production (time reversal symmetry) (14.26)
= decay rate of after production to specific final state . (14.27)
Z e e Z
Z X Z X
LEP
2.5 GeVm
hadronse e
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0 0
0
1
0 00 0
0 0 0 0
0
, ,
1.744 0.00
Recall: branching ratio for a given decay (2.11)
(14.28)
Measure measure
Fits to observed data:
hadrons
itot
Z Z
Z
i B
Z e e Z XB Z e e B Z X
B Z e e B Z X Z e e Z X
Z
0
0 0
0
0
0 0 0
0
2
0.0840 0.0009 , , .
, , .
3
GeV hadrons (14.29)
GeV for each lepton species: (14.30)
Make an assumption that decays only via:
hadrons
hadronsZ
Z Z qq
Z e
Z
Z Z Z
Z Z
0 0
0 0.499 0.004
(14.31)
number of neutrino species
GeV (14.32)
N Z
N
N Z
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There are three light neutrino species
Combined data from LEP experiments
0 0.166
3.00 0.05
GeV (calculated) (14.33)
(14.34)
A stunning result demonstrating the precision of particle physics measurements and theory.
there aren't any heavy chargedleptons with a
Z
N
ssociated light neutrinos.
from anomaly condition: neutrinos are massless there are only 3 generations of leptons and quarks. We've already found the fundamental fermions.
if
This is where we end the story.
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Goal: a theory which describes all of the fundamental constituents of nature and theirinteractions with the minimum of assumptions and free parameters. Ultimately describe all interactions over small distance scales and cosmological observations.The Standard Model is our best attempt at this - assess how successfult it is in lecture 15.
6 quarks, 6 leptons, 3 exchange bosons + antiparticles. Two independent forces (electroweak and QCD).
19 free parameters: particle masses, mixing angles,CP-violating term, couplings....
Consistent method of introducing interactions via so-called gauge invariance and Feynam diagram formalism (next lecture course).
The Standard Model assumes massless neutrinos but this is easily fixed.
Barring neutrino oscillations, the Standard Model has never failed a single experimental test.There is still one test left to pass - finding the Higgs boson.
The Standard Model
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The most rigorous test of the Standard Model to date: g-2
22
From the Dirac equation : Dipole moment and spin for a point-like fermion related by:
; (1.23)
This can be measured by experiments studying the response of an electron in a mag
e eeg S gm
12
12
2 1159652180.7 0.3 102
2 1159652153.5 28 102
netic field. Need to calculate higher orders:
Precision experimental result:
(14.35)
Dirac prediction + quantum corrections:
(14.36)
g
g
Basic interactionwith B field photon
Next to leading order correction
Higher order corrections
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Summary
● Neutral currents Flavour changing vertices
● Electroweak unification and measurement of the Z0 resonance 3 light neutrinos 3 fermion generations
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