1 / 26

Neutral and Charged Current at High–x and High-Q 2 at HERA

Neutral and Charged Current at High–x and High-Q 2 at HERA. Haiping Peng (On behalf of H1 and ZEUS Collaborations). QCD06 Montpellier, France. Outline. Introduction to HERA Deep inelastic scattering and structure functions F 2 , xF 3 measurement

yosef
Download Presentation

Neutral and Charged Current at High–x and High-Q 2 at HERA

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Neutral and Charged Current at High–x and High-Q2 at HERA Haiping Peng (On behalf of H1 and ZEUS Collaborations) QCD06 Montpellier, France

  2. Outline • Introduction to HERA • Deep inelastic scattering and structure functions • F2, xF3 measurement • Polarised neutral and charged current • Summary peng@mail.desy.de 2006-07-04

  3. H1 and ZEUS at HERA Circumference~6.3km P • Proton –electron or positron collider; • Center of mass energy S = 319GeV; • Higher luminosity & polarised beam since 2003; • 2 collider experiments; • Nearly 4 detector coverage 27.5GeV 820/920GeV peng@mail.desy.de 2006-07-04

  4. Deep Inelastic Scattering • At fixed s: two independent kinematic variables: e.g. Q2 & x; • Q2 = “resolving power” of probe, High Q2 : resolve 1/1000th size of proton; • x = momentum fraction of proton carried by struck quark; • y = inelasticity of scattered lepton; Fraction of lepton’s energy transferred to the proton; • Related kinematic quantities; Q2 = Sxy peng@mail.desy.de 2006-07-04

  5. NC&CC Cross Sections NC Cross Section: CC Cross Section: Sensitive to u and d valence quarks at LO QCD peng@mail.desy.de 2006-07-04

  6. Kinematic Plane Coverage • Conventional QCD evolution only tells us Q2 dependence (DGLAP), x dependence must come from data; • HERA cover large region in x and Q2; • At low x : measure gluon PDFs and indirect determination of FL • At high x : measure xF3 and valence quark PDFs; • Large overlap with LHC region in x; x peng@mail.desy.de 2006-07-04

  7. Precision F2 Data HERAI • Sensitive to sum of quark and anti-quark; • Range in x : 0.00001 ~1; Range in Q2 : 1~30000GeV2; • Strong scaling violation, due to QCD gluon radiation, provide indirect constraint on gluon density; • Measured precision: 2 ~3%, still large error at highest Q2 and x; Higher Luminosity at HERAII • Data of HERA experiments in agreement and well described by QCD; peng@mail.desy.de 2006-07-04

  8. xF3 Determination HERAI • Difference between e+p and e-p  xF3 significant at high Q2 only; • Increases electron proton cross section and reduces positron proton cross section at large Q2; e- e+ L(e- p)  15pb-1 L(e+ p)  110pb-1 • Constrains the valence quark content; • Data is well described by QCD (CTEQ6D) and in agreement with global fit PDFs; • Uncertainty from e-p sample, higher luminosity is necessary; HERAII data(170pb-1) will greatly help; peng@mail.desy.de 2006-07-04

  9. HERA I e+p 65.1pb-1 NC at High x • Limitations in beam energies and measurement techniques: HERA x~0.65; • New method : Electron and Jet; Electron  Q2; One Jet  x; No Jet  highest bin xEdge<x<1; • Agree with the expectation of NLO using CTEQ6D PDFs; • A tendency to lie above the expectations at highest x bins; • Produce new constraint on PDFs at the higher values of x. peng@mail.desy.de 2006-07-04

  10. CC Cross Sections HERAI • e+p mostly sensitive to d(x,Q2); while e-p mostly sensitive to u(x,Q2); • e+p cross section is suppressed by factor (1-y)2; • At low Q2, the difference is less pronounce due to the sea quark contribution; • Constraint for the u and d valence quark; • Small cross section  Large statistical error; • Data agrees with NLO QCD global PDFs fit; peng@mail.desy.de 2006-07-04

  11. Polarised NC&CC Cross Sections • HERA upgrade : longitudinally polarized lepton beams ; higher luminosity; • SM Prediction: 1. The cross section dependent on the longitudinal polarization of the incoming lepton beam; 2. CC cross section : Linear function of polarization due to the absence of right-handed charged currents; 3. NC Cross section: decompose into unpolarised and polarised parts; peng@mail.desy.de 2006-07-04

  12. CC Cross Sections • Data: e-p : 2003-2004; e+p : 2005; HERA I; • Linear dependence is firmly established both for e+ and e- beam; • ZEUS and H1 measurements are in good agreement with SM; • Vanishing cross sections for left (right)-handed positrons (electrons); • Consistent with absence of right-handed weak currents; peng@mail.desy.de 2006-07-04

  13. NC Cross Sections e-p H1 e+p H1 • Rise of the ratio RH/LH for e+p; • drop of the ratio RH/LH for e-p;. • Indication of polarization effect on NC cross sections, although significance is moderate; • Well described by the predictions of SM for both H1 and ZEUS;. peng@mail.desy.de 2006-07-04

  14. xF3 at HERAII • Combine polarised data sets, and make small correction for residual polarization  a effective unpolarised date; • Combine HERAI data  xF3; • More precise xF3 measurement; • Data is well described by QCD (CTEQ6D) and in agreement with global fit PDFs; peng@mail.desy.de 2006-07-04

  15. Summary HERA measures proton structure function in a wide range of x and Q2, and plays important role in testing of SM. F2 is precisely measured, scaling violations are well described by pQCD; xF3 measurement at high Q2 is sensitive to valence quark content of proton, but statistically limited for HERAI, much improved at HERAII; CC cross section measurements at high Q2 constrain u and d density; HERAII polarised beam : Linear dependence of CC cross section on polarization is consistent with SM prediction, the absence of right-handed weak currents is confirmed. Effect of polarization in NC interactions is visible but significance is moderate; The coming HERAII polarised and higher luminosity (700pb-1, 2007) data will improve the measurement to a new level precision and enhance the potential in testing of SM. peng@mail.desy.de 2006-07-04

  16. Thanks peng@mail.desy.de 2006-07-04

  17. xG3 at HERAI peng@mail.desy.de 2006-07-04

  18. peng@mail.desy.de 2006-07-04

  19. CC Cross sections .VS. (1-y)2&x • e-p cross section is larger than e+p cross section • Different quark flavors probe by the w boson and the helicity structure of CC interaction • Agree well with SM expectations within errors • (1-y)2 is directly related to the scattering angle  in the electron–quark center-of-mass system; • Isotropic distribution and strong angular dependence on (1-y)2; • Isotropic distribution increase with decreasing x due to the increasing of sea quarks; • At large x, e+p sensitive to d quark; e-p sensitive to u quark; peng@mail.desy.de 2006-07-04

  20. NC at HERAII peng@mail.desy.de 2006-07-04

  21. xF3 at HERAII peng@mail.desy.de 2006-07-04

  22. CC Cross Sections Differential cross sections with different polarizations have the same shape, only the normalization is different! peng@mail.desy.de 2006-07-04

  23. CC & NC Cross sections HEARII HEARI  dominant • Spans more than two orders of magnitude in Q2, the cross section fall with Q2 by about six orders of magnitude for NC. while three orders for CC; • Agreement between H1, ZEUS and QCD fit in cross section; • NC cross section exceeds CC cross section at low Q2 due to the photon exchange in the NC process; • Unification of EM and weak interactions in DIS at high Q2; W boson Z interf. Diff u, d distribution. peng@mail.desy.de 2006-07-04

  24. peng@mail.desy.de 2006-07-04

  25. peng@mail.desy.de 2006-07-04

  26. NC at High x e-p 16.7 peng@mail.desy.de 2006-07-04

More Related