g-2 - KVI

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Transcript g-2 - KVI 

g-2
and the future of physics
Student:
A.C. Berceanu
Supervisors: Olaf Scholten
Gerco Onderwater
Theory
What does g mean?
magnetic dipole moment
• gyromagnetic ratio =
angular momentum
e 
 spin  g
S
2m
positron charge

intrinsic spin angular momentum
spin magnetic dipole moment
mass of particle
g=2? hmm..
• Schrödinger equation postulates g=2 for
pointlike leptons
• Dirac equation (relativistic) actually
produces the g=2 value for isolated
charged, spin ½ particles (particles that
just interact with an external field)
• QED considers radiative corrections (a
charged particle also has its own field),
resulting in g values slightly larger than 2
Why is g important?
• neutron: neutral! => expected g value =0
• experiment: g(neutron) = 3.82608546
e 
n  g
S 0
2m p

• this resulted in the quark model of internal structure (total charge = 0
but contains charged sub-particles)
g
• if CPT invariance holds then electron  1
g positron
•
•
•
•
•
g for the electron is known to a precision of 4ppb
CPT invariance has been tested to 10-12!
determining
(fine structure constant)
testing QED
in case of the muon - constraining the SM and beyond SM physics

Anomaly
• we define the
anomalous
magnetic moment:
g 2
a
2
Theory of leptonic g-2
Radiative corrections:
al ( SM )  al (QED)  al ( HAD)  al (WEAK )
muon: 99.993%
hadronic contribution
vacuum polarization
lbl scattering
higher order vacuum polarization
electroweak contribution
one loop
two loops
The electron and its brothers
Name
Symbol

electron / positron
e /e
muon / antimuon
 /

tauon / antitauon
 /




Electric
charge
-1 / +1
Mass
(GeV/c2)
0.000511
-1 / +1
0.1056
-1 / +1
1.777
muon lifetime: 2.20*10-6 s
tauon lifetime: 2.96*10-13 s
Why do we like the muon?
• because it’s heavy!
2
 melectron 
 ae (QED )
a (QED )  
 mmuon 
• increased sensitivity to higher mass scale
radiative corections of about 40.000!
• at 0.5ppm the muon anomaly is sensitive to
>100GeV scale physics
Why don’t we like the tauon that
much?
• after all, it’s even heavier!
• the strong and weak interaction correction
would be enhanced by a 1.2*107 factor
• well.. yes, but its lifetime is also 10-7 times
shorter compared to the muon
• that makes measuring its anomalous
magnetic moment almost impossible (at
least for now)
What do we want to know?
what needs to be calculated is the
strength of a charged particle’s interaction
with a magnetic field
the g factor sets the strength of an
electron’s interaction with a magnetic
field
the problem is: given a particle of know mass, charge and momentum
interacting with a known magnetic field, how much will the particle’s path be
deflected when it passes through the field?
classical electrodynamics considers lines of magnetic flux that induce a
curvature in the particle’s trajectory
QED – different approach: local scattering events that can be understood
in terms of Feynman diagrams
The first step..
Feynman diagrams – purely
symbolic representations of
all the ways that a particular
event can happen – they do
NOT represent particle
trajectories!
time
space
internal lines in the
diagrams represent
particles that cannot be
observed – virtual particles;
only external lines (which
enter and leave the
diagram) are real particles
a virtual particle does not carry
the same mass as its real
counterpart – actually, it can have
any mass whatsoever!
E 2  p 2c 2  m2c 4
Feynman diagrams
• external lines describe the physical process
• internal lines describe the mechanism involved
• first you draw all the diagrams with appropriate
external lines (and different number of internal
loops), then you evaluate each contribution
(using conservation of energy and momentum at
each vertex) and add it all up!
• well, but the number of diagrams is infinite!
• fortunately, each vertex introduces a factor of α,
so the more loops it has the less it will contribute
to the sum total
QED contribution
 
 
al (QED )   An     Bn (l , l ' ) 
   n 2
 
n 1
n
n

 
 
 
 
a (QED ) 
 0.765..   24.05..   125.0..   930..   ..
2
 
 
 
 
2
1 diagram
1

137
7 diagrams
fine structure
constant
3
72 diagrams 891 diagrams
4
5
12,672 diagrams!
QED loops involve only virtual
photons and leptons
It’s just perturbation theory!
• the reason we can write this QED series
expansion in the powers of the coupling constant,
 , is because  is so small
• unfortunately, as we will see in the next
presentations, we cannot do that for the case of
QCD, where the coupling constant is of the order
of 1, so the hadronic contributions are much
harder to evaluate (much harder to calculate
anything with a non-perturbative theory)
The 7 two-loop diagrams
vacuum polarization
Vacuum polarization
• the true vacuum contains short-lived virtual particleantiparticle pairs which are created and then annihilate
each other
• some of them turn out to be charged (i.e. electron –
positron pairs)
• such charged particles act as an electric dipole
• in the presence of an electric field (eg the EM field
around an electron), these particle-antiparticle pairs
reposition themselves, partially counteracting the field
(like a dielectric screening effect)
• the field would therefore be weaker than expected when
the vacuum would be completely empty
Hadronic vacuum polarization
• since the particles interact
strongly, the internal
composition of the loop is very
difficult to analyze
• however, by applying
dispersion theory, one can “cut
in half”, giving a diagram which
describes the production of
real (non-virtual) hadrons
• so it is possible to relate the
total cross-section for hadronic
production in e+e- scattering to
the effect on the anomaly
real hadrons
And the 72 3-looped ones!
Light by light scattering
• photon-photon
interactions
• it also occurs mediated
by virtual hadrons in
“hadronic light by light
scattering”
• this is the most difficult
contribution to evaluate
theoretically (one cannot
apply experimental data
and dispersion theory)
Most accurate QED test
• in the case of the electron (for which QED
corrections represent by far the main
contribution) we can determine  indirectly by
comparing the a value with experiment
• the current experimental precision in ae is
1.2ppb!
• we can also determine  directly
(experimentally) i.e. from the quantum Hall effect
• comparing the two, QED has been tested to 10-12
precision!
Experiment
Cyclotron motion

charged
 lepton with velocity v moving perpendicular to uniform magnetic
field B
eB
c 
, 
mc
1
v2
1 2
c
Spin precession
• in the laboratory frame,the spin motion will be a
uniform precession of S at the spin precession
frequency:
g
S  c  (1   )c
2
precession frequency for lepton
in unaccelerated motion
Thomas precession due to acceleration
caused by magnetic field
Relative precession of S with
respect to v
Putting it all together


• the relative precession of S with respect to v will
occur at a frequency:
eB
 a   S  C  a
mc
• completely independent of velocity!
• one can measure g-2 directly (and gain 3 decimal
places of precision for free, because g-2 is about
1/1000 of g)!
g-2 experiments
• the highest experimental precision was achieved
by measuring the electron g factor
• this involves a single electron (or positron)
moving in a trap region of high (5T) magnetic
field at 4K temperature
• although the classical motion of the electrons
can be described as a combination of
frequencies, like the muons, there are “slight”
differences in the two experiments:
g-2 experiments (II)
• instead of one electron we have millions of
muons which contribute
• the electrons have evergies in the region
of 1 meV, while the muons are highly
relativistic (3.1 GeV)
• the electrons are trapped on cyclotron
orbits of around 10-6m whereas the muons
follow orbits of 7m!
Muon g-2 experiment: BNL E821
Some numbers
• the muons will have p=3.094 GeV/c, and
this will result in a relativistic dilation of
their lifetime (in the laboratory frame), from
2.2µs to 64µs
• on average, they will perform 432
revolutions around the ring in one lifetime
• 14.7 g-2 periods in one lifetime
The time spectrum of electrons
• muon decay is a three-body decay, so
they will produce a continuum of electrons
from the end-point energy (3.1GeV) down
• since the high energy electrons are
correlated with the muon spin, if one
counts hight energy electrons as a
function of time one gets an exponential
from muon decay modulated by the g-2
precession
The time spectrum of electrons (II)
N (t )  N 0e

t

1  A cos(at   )
by fitting this spectrum (and making
the appropriate corrections) one
can get the value of  a , and
therefore the value of the anomaly
can be calculated
From an ideal g-2 experiment to a
real one
1
a 
t
• the uncertainty in
, where t = storage
time, therefore:
• requirement 1: the particle must be trapped for
a long time
vacuum
homogenous magnetic field
• requirement 2: need to measure with great
precision the average magnetic field (B) “felt” by
the particles (also, they must all feel the same
field)
From an ideal g-2 experiment to a
real one (II)
• requirement 3: for maximum accuracy, the magnetic field
value should be as high as possible without jeopardizing
good field uniformity
• the beam will have some angular divergence, so it will
contain particles whose component of the velocity along
the magnetic field lines is not 0!
• requirement 4: focusing electric field (quadruplore field)
to provide vertical focusing of the muon beam
• this electric field doesn’t affect the measurement because
of the “magic”

Magic gamma
• with the addition of the focusing electric field, the
precession frequencies become:

  e  B      
c      2   E 
 mc      1 


   
  e  B  1   
  E  a ( B    E )
s     
 mc      1 

  
 e    1
a  s  c   a B   2  a   E 
 mc 
  1





  29.3..
The moment of truth
Conclusions
• g-2 experiments on electrons represent the most
stringent test of QED
• g-2 of the muon is also sensitive to outside-QED
(and perhaps even outside SM contributions)
• muon g-2 constrained the SM for many years
• an enormous amount of theoretical work
continues worldwide to improve the knowledge
on hadronic contributions
• you will hear more about strong interactions in
the upcoming presentations
Conclusions (II)
• we will soon hopefully have a single SM
prediction instead of two different ones!
• the experimental measurements will also be
improved by a factor 2 ½ over the next few years
• the current discrepancy between the BNL and
SM values of g-2 may indicate new physics in
loop processes, internal structure of leptons or
SUSY type theories, but at the present stage it is
all pure speculation
Bibliography
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Advanced Series on Directions in High Energy Physics – Vol. 7, “Quantum Electrodynamics”,
Editor T. Kinoshita, pag. 479-504
“QED: The strange theory of light and matter”, Richard P. Feynman,1985
American Scientist, Vol. 92, No. 3, May-June 2004, pag. 212-216
Hughes, V.W., and T. Kinoshita, 1999: “Anomalous g values of the electron and muon.”, Reviews
of Modern Physics 71(2):S133-S139
Muon g-2 Collaboration (G.W. Bennet et al.). Preprint. “Measurement of the negative muon
anomalous magnetic moment to 0.7 ppm.” http://arxiv.org/abs/hep-ex/0401008
Muon g-2 Collaboration (G.W. Bennet et al.) “Measurement of the positive muon anomalous
magnetic moment to 0.7 ppm.” Phys. Rev. Lett. 89, 101804 (2002)
Nyffeler, Andreas. Preprint. “Theoretical status of the muon g-2.” http://arxiv.org/abs/hepph/0305135
R.M. Carey et al. "An improved Muon (g-2) Experiment at J-PARC“, J-PARC Letter of Intent L17
(2003)
Arthur Rich, John C. Wesley, “The Current Status of the Lepton g Factors”, Reviews of Modern
Physics, Volume 44, Number 2
Andrzej Czarnecki, “Anomalous magnetic moments of free and bound leptons”, QED 2005, Les
Houches, June 2005