Revisiting NuTeV -or- What Kevin Did Last Week

1. Revisiting NuTeV-or-What Kevin Did Last Week Kevin McFarland Rochester Neutrino Group Meeting 21 February 2011

2. The Big Picture • Neutrinos are important in electroweak physics • there is a glorious history, of course… • … but precision today in neutrino electroweak couplings lags behind other sectors • neutrino couplings are the most difficult couplings to measure precisely at the Z0 pole • matter effects in ν oscillations are sensitive to only flavor non-diagonal couplings • Some outstanding puzzles in neutrino physics • ~3σNuTeV result σ(νq→νq)/σ(νq→μq’) • ~2σ deficit in “Nν” LEP measurement of Γ(Z0→νν) • To date, only ~5% precision on σ(νe→νe) NuTeV Revisited, K. McFarland

4. NuTeV Measurement Technique • Measure nNC/CC ratio to extract ratio of weak couplings • ratio is experimentally and theoretically robust • largest uncertainty: suppression of charm production in CC (mc) • can extract sin2qW. NuTeV measurement often quoted this way. • With neutrino and anti-neutrino beams, can form Charged-Current(CC) Neutral-Current(NC) NuTeV Revisited, K. McFarland

5. Dipoles make sign selection - Set n /n type - Remove ne from KL (Bkgnd in previous exps.) NuTeV Sign-Selected Beamline • Beam identifies neutral currents as n or n(n in n mode 310-4, n in n mode 410-3) • Beam only has ~1.6% electron neutrinos  Important background for NC events since no final state muon NuTeV Revisited, K. McFarland

6. Paschos-Wolfenstein à la NuTeV NuTeV fit for sin2θWand mc given external constraint from strange sea analysis. (More later) • NuTeV result: • Statistics dominate uncertainty • EWK fit (LEPEWWG 2001): • 0.2227  0.00037, a 3s discrepancy NuTeV Revisited, K. McFarland

7. QCD SymmetryViolations What symmetry violations can affect the result? u≠d in target (neutron excess) asymmetric heavy seas

8. Symmetry Violating QCD Effects • Paschos-Wolfenstein R- assumptions: • Assumes total u and d momenta equal in target • Assumes sea momentum symmetry, s =s and c =c • Assumes nuclear effects common in W/Z exchange • To get a rough idea offirst two effects, can calculate them for R- NuTeV Revisited, K. McFarland

9. Asymmetric Strange Sea Why it might be so How it is measured at NuTeV This is what drives us to update the NuTeV measurement

10. A Very Strange Asymmetry • Paschos-Wolfenstein relation assumes that strange sea is symmetric, i.e., no “valence” strange distribution • if there were on, this would be a big deal since it is an isovector component of the PDFs(charm sea is heavily suppressed) • ~30% more momentum in strange sea than in half of strange+anti-strange seas would “fix” NuTeV sin2θW • Why might one think that the strange and anti-strange seas would be different? • Perturbative strange sea is (roughly) momentum symmetric… • But “intrinsic” strange sea need not be! • so is a DIS probe of intrinsic strangeness! • Brodsky first suggested it! (though this model at right is excluded by NuTeV data) G.P. Zeller et al., Phys.Rev.D65:111103,2002) Brodsky and Ma, Phys. Let. B392 NuTeV Revisited, K. McFarland

11. How Does NuTeV Measure This? • m± from semi-leptonic charm decay • Fits to NuTeV and CCFR n and dimuon data can measure the strange and antistrange seas separately • NuTeV separate n and beams important for reliable separation of s ands NuTeV Revisited, K. McFarland

12. NEW NuTeV NLO Analysis • Have incorporated CTEQ strange “valence” evolution and CTEQ parameterizations • thanks esp. to Amundson, Kretzer, Olness & Tung • NuTeV NLO analysis (Phys.Rev.Lett.99:192001,2007) is near zero, but slightly positive • will shift central valuetowards standard modeland increase uncertainties • at NLO, with CTEQ6 as base PDF courtesy heroic efforts of D. Mason, P. Spentzouris NuTeV Revisited, K. McFarland

13. NuTeV Update Effects incorporated Numerical Estimations To do

14. What’s Done? • Three large effects • Estimate for Strange Sea, S-/S+~0.09±0.04 • External K+e3 branching ratio • Brookhaven E-865, famous for “fixing” the unitarity of the first row of the CKM matrix • also improves agreement with our own (less precise) measurement of νe flux • Strong effect on our electron neutrino background • d/u PDF uncertainties • pointed out by Kulagin and Alekhin that these were underestimated in published result • also corrected target neutron excess NuTeV Revisited, K. McFarland

15. Changes in Prediction of Rν published: updated: NuTeV Revisited, K. McFarland

16. NuTeV 99% Conf. Prediction Graphical Shifts in Rν mtop d/u νe Strange Sea, S-/S+=0.09 NuTeV Revisited, K. McFarland

17. NuTeV 99% Conf. Prediction Directions of Effects not Considered(length of arrows are arbitrary) Shadowing (VMD) mc Valence Isospin Violation NuTeV Revisited, K. McFarland

18. What Are you Working on Now? • Current Work is on Improving Cross-Section Model • LO to NLO QCD cross-section • Higher twist (non-perturbative) effects smaller • Can build on better fits (global!) to two muon data to constrain charm • Base data for cross-section comes from NuTeV (previous analysis used CCFR) • It’s “the gift that keeps on giving”… NuTeV Revisited, K. McFarland

19. What if We Don’t “Fix” NuTeV? • My money is on the second symmetry violating term, • We may have discovered large (several %) isospin violation in parton distributions NuTeV Revisited, K. McFarland