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Electroweak Physics Lecture: Top Quark Mass Measurements & Low Energy Testing

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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Electroweak Physics Lecture: Top Quark Mass Measurements & Low Energy Testing

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  1. Electroweak PhysicsLecture 5

  2. 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

  3. Top Event in the Detector Nicest decay mode: Ws decay to lepton+jets • 2 jets from W decay • 2 b-jets • ℓ±νℓ

  4. Top Event Reconstruction

  5. 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

  6. Top Mass: Matrix Element Method

  7. 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:

  8. Top Mass: Template Method • Dependence of reconstructed mass on true mass parameterized from fits to MC • Include background templates constrained to background fraction

  9. Top Quark Mass Results

  10. Top Quark Cross Section • Test of QCD prediction:

  11. 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

  12. 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

  13. 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!

  14. 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

  15. 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

  16. 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%

  17. 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:

  18. Tree Level Diagrams • Photon exchange will be dominant • Asymmetry between L and R terms (parity violation) is from Z-exchange → small asymmetry

  19. 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

  20. NuTeV • NuTeV = neutrinos at the Tevatron • Inelastic neutrino-hadron scattering • Huge chunk of instrumented iron • With a magnet!

  21. NuTeV Physics • Two interactions possible: • Neutral Current (NC) Charged Current (CC) • Pachos Wolfenstein Relationship • Requires both neutrino and anti-neutrino beams No γ* interference

  22. 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

  23. Events in the Detector “Event Length” used to separate CC and NC interactions

  24. NuTeV Result • Doesn’t agree with Z pole measurements

  25. 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

  26. sin²θW(Q) Results Some disquiet in the Standard Model, perhaps?

  27. 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…

  28. End of lecture • Precision measurements on muons follow

  29. 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

  30. Prediction for the Lifetime

  31. Highly polarized + + stop in Al target(several kHz) Unbiased + (scintillator) trigger TWIST Experiment At TRIUMF in Vancouver

  32. m e+ Typical Decay Event

  33. Muon Decay Spectrum • SM predictions and measurements:

  34. 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

  35. Very Precisely Predicted…

  36. 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

  37. E821

  38. Decay Curve Oscillations due to parity violation in muon decay Use ωa from fit

  39. aμ: Results and Comparison Very precise measurement! Another hint of a problem?

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