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Detailed overview of top quark mass measurements, low energy electroweak tests including muon precision measurements and matrix element methods in experimental physics. Also covers Tevatron and LEPII findings.
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Contents • Top quark mass measurements at Tevatron • Electroweak Measurements at low energy: • Neutral Currents at low momentum transfer • normally called low Q2 • Q is the four momentum of the boson • Precision measurements on muons • We didn’t get to this in the lecture • Slides are at the end
Top Event in the Detector Nicest decay mode: Ws decay to lepton+jets • 2 jets from W decay • 2 b-jets • ℓ±νℓ
Top Mass: Largest Systematic Effect • Jet Energy Scale (JES) • How well do we know the response of the calorimeters to jets? • In Lepton+Jets channels: 2 b-jets, 2 jets from W→qq, ℓ+ν • Use jets from W decay (known mass) to calibrate JES • Example of CDF analysis: JES = −0.10 +0.78/−0.80 sigma Mtop = 173.5 +2.7/-2.6 (stat) ± 2.5 (JES) ± 1.5 (syst) GeV/c2 simulation ~16% improvement on systematic error
Matrix Element Method in Run II • Probability for event to be top with given mtop: • Use negative log likelihood to find best value for mtop:
Top Mass: Template Method • Dependence of reconstructed mass on true mass parameterized from fits to MC • Include background templates constrained to background fraction
Top Quark Cross Section • Test of QCD prediction:
Search for Single Top Production • Can also produce single top quarks through decay of heavy W* boson • Probe of Vtd • Search in both s and t channel • Currently limit set <10.1 pb @ 95%C.L. • Don’t expect a significant single until 2fb-1 of data are collected
W helicity in Top Decays • Top quarks decay before then can hadronise • Decay products retain information about the top spin • Measure helicity of the W to test V-A structure of t→Wb decay • F+α mb²/mW²≈0 • Use W→ℓν decays • Effects in many variables: • pT, cosθ* of lepton • mass of (lepton+jet) CDFII 200pb−1 No discrepancies found, need more data for precision
Tevatron Summary: mtop and MW • CDF and DØ have extensive physics programme • Most important EWK measurements are MW and mtop • Stated aim for RunII: • mtop ±2.5 GeV/c2 • MW to ±40 MeV/c2 • Probably can do better • Other EWK tests possible too!
Two More Measurements for Our Plot Extracted from σ(e+e−→ff) Afb (e+e−→ℓℓ) τ polarisation asymmetry b and c quark final states ALR Tevatron + LEPII From Tevatron
Electroweak Physics at Low Energy • Low momentum transfer, Q, of the boson • Test whether EWK physics works at all energy scales • Møller Scattering • Neutrino-Nucleon Scattering • Atomic Parity Violation Plus: muon lifetime and muon magnetic moment
Running of sin²θW • The effective value of sin²θeff is depend on loop effects • These change as a function of Q², largest when Q²≈MZ, MW • Want to measuresin²θeff at different Q² • For exchange diagram ~2.5%
E158: Møller Scattering • e−e−→e−e− scattering, • first measurement at SLAC E158 in 2002 and 2003 • Beam of polarised electrons <Pe> ≈ 90%, Ee=48.3GeV • Both L and R handed electron beams • Incident on liquid hydrogen target • Average Q² of 0.027 (GeV/c)² (Qboson~0.16 GeV/c) • Measure asymmetry between cross section for L and R beams:
Tree Level Diagrams • Photon exchange will be dominant • Asymmetry between L and R terms (parity violation) is from Z-exchange → small asymmetry
Measured Asymmetry • A = −131 ± 14 (stat) ± 10 (syst) ppb • sin2θWeff(Q2=0.026) = 0.2397 ± 0.0010 (stat) ± 0.0008 (syst) • cf 0.2381 ± 0.0006 (theory) +1.1σ difference
NuTeV • NuTeV = neutrinos at the Tevatron • Inelastic neutrino-hadron scattering • Huge chunk of instrumented iron • With a magnet!
NuTeV Physics • Two interactions possible: • Neutral Current (NC) Charged Current (CC) • Pachos Wolfenstein Relationship • Requires both neutrino and anti-neutrino beams No γ* interference
NuTeV Beams • Beam is nearly pure neutrino or anti-neutrino • 98.2% νμ1.8% νe • Nu beam contamination < 10³ • Anti-nu beam contamination < 2 x 10³
Events in the Detector “Event Length” used to separate CC and NC interactions
NuTeV Result • Doesn’t agree with Z pole measurements
Atomic Parity Violation • Test Z and γ interaction with nucleons at low Q² • Depends on weak charge of nucleon: • Large uncertainty due to nuclear effects • eg nucleon spin
sin²θW(Q) Results Some disquiet in the Standard Model, perhaps?
Low Energy Summary • Important to test EWK Lagrangian at different energy scale • Challenging to achieve the level of precision to compare with theory! • Experimental Challenges overcome, very precise results achieved • Some (small) discrepancies found between data and theory…
End of lecture • Precision measurements on muons follow
Muon Lifetime • The lifetime of the muon is one of the test predicted parameters in the EWK • μ+ → e+ νe νμno hadronic effects • One of the most precisely measured too, use it to set GF in the Lagrangian • No recent measurement of just lifetime, current investigations of decay spectrum τ(μ)=(2.19703 ± 0.00004)X10−6
Highly polarized + + stop in Al target(several kHz) Unbiased + (scintillator) trigger TWIST Experiment At TRIUMF in Vancouver
m e+ Typical Decay Event
Muon Decay Spectrum • SM predictions and measurements:
Muon Dipole Moment • The Dirac equation predicts a muon magnetic moment: • Loop effects make gμ different from 2 • Define anomalous magnetic moment: with gμ=2
The Experiment: E821 at Brookhaven • polarised muons from pion decay • procession proportional to aμ: ω=ω(spin)−ω(cyclontron) • Precise momentum tuning, γ=29.3
Decay Curve Oscillations due to parity violation in muon decay Use ωa from fit
aμ: Results and Comparison Very precise measurement! Another hint of a problem?