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Our Understanding of Sea Quarks in the Nucleon

Weekly Journal Club for Medium Energy Physics at IPAS 2011/1/10. Our Understanding of Sea Quarks in the Nucleon. Wen-Chen Chang 章文箴 Institute of Physics, Academia Sinica. Inelastic Electron Scattering. Q 2 : Four-momentum transfer x : Bjorken variable (=Q 2 /2 M n )

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Our Understanding of Sea Quarks in the Nucleon

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  1. Weekly Journal Club for Medium Energy Physics at IPAS 2011/1/10 Our Understanding of Sea Quarks in the Nucleon Wen-Chen Chang 章文箴 Institute of Physics, Academia Sinica

  2. Inelastic Electron Scattering Q2 :Four-momentum transfer x : Bjorken variable (=Q2/2Mn) n : Energy transfer M : Nucleon mass W : Final state hadronic mass

  3. Structure Function F2(Q2,x)

  4. Describing F2 behavior with partons Lots of partons at small x! CTEQ School 2005

  5. u valence gluon (x 0.05) d sea (x 0.05) Unpolarized Parton Distributions (CTEQ6)

  6. What is Origin of Sea Quarks? • Extrinsic: the sea quarks solely originate from the splitting of gluons, emitted by valence quarks.

  7. Is in the proton? = Gottfried Sum Rule

  8. Experimental Measurement of Gottfried Sum New Muon Collaboration (NMC), Phys. Rev. D50 (1994) R1 SG = 0.235 ± 0.026 ( Significantly lower than 1/3 ! )

  9. Explanations for the NMC result • Uncertain extrapolation for 0.0 < x < 0.004 • Charge symmetry violation • in the proton Need independent methods to check the asymmetry, and to measure its x-dependence !

  10. xtarget xbeam Drell-Yan process: A laboratory for sea quarks Detector acceptance chooses xtarget and xbeam. • Fixed target  high xF = xbeam – xtarget • Beam nucleon: valence quarks at high-x. • Target nucleon: sea quarks at low/intermediate-x. • Measure ratio of DY process from hydrogen and deuterium:

  11. Light Antiquark Flavor Asymmetry: Brief History • Naïve Assumption: • NMC (Gottfried Sum Rule) • NA51 (Drell-Yan, 1994) NA 51 Drell-Yan confirms d(x) > u(x)  

  12. Light Antiquark Flavor Asymmetry: Brief History • Naïve Assumption: • NMC (Gottfried Sum Rule) • NA51 (Drell-Yan, 1994) • E866/NuSea (Drell-Yan, 1998)

  13. Main Injector 120 GeV Tevatron 800 GeV Advantages of 120 GeV Main Injector The future: Fermilab E906 • Data taking planned in 2010 • 1H, 2H, and nuclear targets • 120 GeV proton Beam The (very successful) past: Fermilab E866/NuSea • Data in 1996-1997 • 1H, 2H, and nuclear targets • 800 GeV proton beam • Cross section scales as 1/s • 7x that of 800 GeV beam • Backgrounds, primarily from J/ decays scale as s • 7x Luminosity for same detector rate as 800 GeV beam • 50x statistics!! Fixed Target Beam lines

  14. Extracting d-bar/-ubar From Drell-Yan Scattering Ratio of Drell-Yan cross sections (in leading order—E866 data analysis confirmed in NLO) • Global NLO PDF fits which include E866 cross section ratios agree with E866 results • Fermilab E906/Drell-Yan will extend these measurements and reduce statistical uncertainty. • E906 expects systematic uncertainty to remain at approx. 1% in cross section ratio.

  15. Deep-Inelastic Neutrino Scattering

  16. Adler Sum Rule

  17. Strange Quark and Anti-quark in the Nucleon CCFR, Z. Phys. C 65, 189 (1995)

  18. Strange Quark and Antiquark in the Nucleon NuTeV, PRL 99, 192001 (2007)

  19. Semi-inclusive DIS

  20. Strange Quarks from Charged-Kaon DIS Production HERMES, Phys. Lett. B 666, 446 (2008)

  21. Asymmetry of W Production and Flavor Asymmetry of Nucleon Sea p+p at sqrt(s)=14 TeV Yang, Peng, and Groe-Perdekam, Phys. Lett. B 680, 231 (2009)

  22. CMS Measurement of W Asymmetry at sqrt(s)=7 TeV Measured W-asymmetry is consistent with the prediction from the PDF with a flavor asymmetry of sea quarks. CMS, arXiv:1012.2466

  23.  Origin of u(x)d(x): Valence quark effect? • Pauli blocking • guu is more suppressed than gdd in the proton since p=uud (Field and Feynman 1977) • pQCD calculation (Ross Sachrajda) • Bag model calculation (Signal, Thomas, Schreiber) • Chiral quark-soliton model (Diakonov, Pobylitsa, Polyakov) • Instanton model (Dorokhov, Kochelev) • Statistical model (Bourrely, Buccella, Soffer; Bhalerao) • Balance model (Zhang, Ma) The valence quarks affect the Dirac vacuum and the quark-antiquark sea.

  24. Balance Model • A physical hadron state is expanded by a complete set of quark-gluon Fock states • The parton numbers of quarks and gluons in the proton are • Splitting and recombination gqqbar qqg

  25. Balance Model (Phys. Lett. B 523 (2001) 260-264) • More u valence quark in the proton leads to more recombination and thus less ubar. • Inclusion of gqqbar does not affect the result of flavor asymmetry.

  26.  Origin of u(x)d(x): Non-perturbative effect? • Meson cloud in the nucleons (Thomas, Kumano): Sullivan process in DIS. • Chiral quark model(Eichten, Hinchliffe, Quigg; Wakamatsu): Goldstone bosons couple to valence quarks.   The pion cloud is a source of antiquarks in the protons and it lead to d>u.

  27. Meson Cloud Model • Virtual  is emitted by the proton and the intermediate state is  + baryons.

  28. Chiral Quark Model • Virtual  is emitted by the constituent quark.

  29. Proton Structure: Remove perturbative sea • There is a gluon splitting component which is symmetric • Symmetric sea via pair production from gluons subtracts off • No Gluon contribution at 1st order in s • Nonperturbative models are motivated by the observed difference • A proton with 3 valence quarks plus glue cannot be right at any scale!! Greater deviation at large-x Paul E. Reimer, Physics Division, Argonne National Laboratory

  30. Intrinsic Sea Quark? • Brodsky et al. (1980) proposed an “intrinsic” (long time-scale) charm component in the proton (PLB 93,451; PRD 23, 2745). • A decomposition of |uudccbar> Fock state for proton. The intrinsic charm component is distributed at relatively large x region and could explain the large cross-section for charm production at large xf in hadron collisions. • Jen-Chieh and I are considering to extend this 5q model to describe the non-singlet distributions of (dbar-ubar) and (ubar+dbar-s-sbar), which are independent of the contributions from “extrinsic” sea quarks.

  31. Sea quarks in

  32. Sea quarks in

  33. Sea quarks in

  34. Sea quarks in The light quark distribution in 5q configuration, which is assumed to be intrinsic, is consistent with the non-singlet distribution of (dbar-ubar).

  35. Sea quarks in

  36. W production at the LHC is sensitive to the gluon distribution function. Tevatron: W production is dominated by a LO process with two valence quarks. LHC: The LO contribution must involve a sea quark; and the NLO contribution from a gluon is significant.

  37. ?

  38. Interesting Topics Missing in This Talk • Transverse spin structure of sea quarks. • Transverse momentum distribution of sea quarks. • The correlation of these two properties. • Flavor asymmetry of these two properties. • Interpretations from the Lattice QCD.

  39. Conclusion • From DIS, DY and SIDIS processes, the structure of sea quarks in the nucleon are explored. • A large asymmetry between dbar and ubar was found at intermediate-x regions. The origin can be interpreted under the meson cloud model, chiral soliton model, intrinsic 5q model and etc. The intrinsic non-perturbative effect rather than extrinsic perturbative gluon-splitting seems more likely to be the cause. • No large asymmetry was observed for s and sbar. • The E906/FNAL and LHC experiments are expected to extend the measurement of sea quarks to the high-x regions where the existing uncertainties are large. • Precise understanding of sea quark distribution is important for the search of BSM in LHC.

  40. References • C. Grosso-Pilcher and M. J. Shochet, Annu. Rev. Nucl. Part. Sci. 36 (1986) 1. • S. Kumano, Physics Reports 303 (1998) 183. • J.M. Conrad and M.H. Shaevitz, Rev. Mod. Phys. 70 (1998) 1341. • P.L. McGaughey, J.M. Moss and J.C. Peng, Annu. Rev. Nucl. Part. Sci. 49 (1999) 217. • G.T. Garvey and J.C. Peng, Prog. in Part. And Nucl. Phys. 47 (2001) 203. • J.C. Peng, Eur. Phys. J. A 18 (2003) 395. • J.T. Londergan, J.C. Peng, and A.W. Thomas, Rev. Mod. Phys. 82 (2010) 2009.

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