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KINETIC MODEL RESULTS FOR HEAVY-QUARK COALESCENCE

R. L. THEWS UNIVERSITY OF ARIZONA Characterization of the Quark Gluon Plasma with Heavy Quarks 25-28 JUNE 2008 Physikzentrum Bad Honnef. KINETIC MODEL RESULTS FOR HEAVY-QUARK COALESCENCE. IN-MEDIUM FORMATION (REGENERATION). HIGH ENERGY EVOLUTION OF MATSUI-SATZ:

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KINETIC MODEL RESULTS FOR HEAVY-QUARK COALESCENCE

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  1. R. L. THEWS UNIVERSITY OF ARIZONA Characterization of the Quark Gluon Plasma with Heavy Quarks 25-28 JUNE 2008 Physikzentrum Bad Honnef KINETIC MODEL RESULTS FOR HEAVY-QUARK COALESCENCE

  2. IN-MEDIUM FORMATION(REGENERATION) HIGH ENERGY EVOLUTION OF MATSUI-SATZ: Rplasma screening < Rquarkonium SUPPRESSION in a static medium, or KHARZEEV-SATZ:Ionization with deconfined gluons Charm pair diffuse away, will not recombine during deconfinement phase or at hadronization NEW SCENARIO AT COLLIDER ENERGIES

  3. Multiple ccbar pairs in high energy AA Collisions • 10-15 from extrapolation of low energy • 20 from PHENIX electrons • 40 from STAR electrons and Kp CENTRAL VALUES AT RHIC: AND AT LHC: 100-200??

  4. PROBE REGION OF COLOR DECONFINEMENT WITH MULTIPLE PAIRS OF HEAVY QUARKS • Two Distinct Physical Scenarios: • Form Quarkonium in the Medium, where it competes with Suppression, and/or • (2) Form Quarkonium during the Hadronization Transition

  5. QUARKONIUM FORMATION MODELS IN REGION OF COLOR DECONFINEMENT • STATISTICAL HADRONIZATION: P. Braun-Munzinger, J. Stachel, Phys. Lett B490 (2000) 196 [nucl-th/0007059]. • KINETIC IN-MEDIUM FORMATION: R. L. Thews, M. Schroedter, J. Rafelski, Phys. Rev. C63 (2001) 054905 [hep-ph/0007323].

  6. COLOR DECONFINEMENT ALLOWS THE INCOHERENT RECOMBINATION OF ALL PAIRS OF HEAVY QUARKS

  7. MANY THEORETICAL INPUT PARAMETERS

  8. Gold-plated signature for Regeneration SEARCH FOR J/PSI with xF > 1

  9. OFF-DIAGONAL PAIRS POPULATE X_F > 1.0

  10. FORMED J/PSI ALSO POPULATES X_F > 1.0

  11. THE P_T DISTRIBUTION IS PEAKED NEAR ZERO

  12. BUT THEY ONLY APPEAR NEAR THE RAPIDITY BOUNDARY

  13. CAN Y AND PT SPECTRA ALONE PROVIDE SIGNATURES OF IN-MEDIUM FORMATION? R. L. Thews and M. L. Mangano Phys. Rev. C73, 014904 (2006) [nucl-th/0505055] • Generate sample of ccbar pairs from NLO pQCD (smear LO qt) • Supplement with kt to simulate initial state and confinement effects • Integrate formation rate using these events to define particle distributions (no cquark-medium interaction) • Repeat with cquark thermal+flow distribution (maximal cquark-medium interaction)

  14. All combinations of c and cbar contribute • Total has expected (Nccbar)2 / V behavior • Prefactor is integrated flux per ccbar pair • Do the J/Psi spectra retain a memory of the underlying charm quark spectra?

  15. No REGENERATION FOR ppJ/Psi, DIAGONAL PAIRS ALONE SHOULD FIT SPECTRA

  16. EXTRACT ALLOWED <kT2> = .75 GeV2

  17. DIAGONAL PAIRS – NO EXTRA PARAMETERS

  18. Use dAu broadening to determine nuclear kt (Minimum Bias)

  19. Central rapidity data exhibits anti-broadening!

  20. Proceed with analysis for muon data only: Collision numbers nbar correlated with centrality Nuclear broadening from Initial state parton scattering, extract l2 = 0.56 +/- 0.08 GeV2 for Au-Au at RHIC, compare with 0.12 +/- .02 GeV2 at fixed-target energy. Note: l and n are correlated within given nuclear geometry. S. Gavin and M. Gyulassy, Phys. Lett. B214 (1988)

  21. Initial lambda estimate disfavors Direct Production

  22. Revised lambda value allows 100% Direct Production

  23. Regeneration is almost independent of centrality and lambda , and magnitude consistent with initial PHENIX data.

  24. Comparison with Thermal + Transverse Flow c-Quark Distributions (Blast Wave) K.A.Bugaev, M. Gazdzicki, M.I.Gorenstein, Phys.Lett.B544,127(2002) S.Batsouli, S.Kelly, M.Gyulassy, J.L.Nagle, Phys.Lett.B557,26 (2003)

  25. Determine fraction of regeneration using y=0 data

  26. Consider combination of Direct and Regeneration (pQCD) with weights (1-a) and a, match data at y = 0

  27. Predict pT Spectra which are in agreement with Data

  28. Comparison with coalescence model: V Greco, C. M. Ko, R. Rapp, Phys. Lett. B595:202 (2004)

  29. WHERE IS FORMATION FROM THERMAL CHARM?

  30. SUMMARY In-Medium Formation (AKA regeneration, coalescence, recombination) as a mechanism for J/y production in central Au-Au at RHIC must reflect the underlying charm quark distributions. We find that normalized pT and y spectra alone can provide signatures of in-medium formation, independent of the absolute magnitude of recombination processes. We show that variation of <pT2> with centrality provides characteristic signals. Baseline tests using pp and pA collisions provides a connection with initial pQCD charm quark distributions.

  31. Centrality dependence and shapes of spectra are consistent with a 10 – 20% fraction produced in-medium from recombination of pQCD charm quarks. • PHENIX measurements of y spectra in AA • collisions now exhibit some narrowing as predicted for in-medium formation. • pT spectra do not indicate an obvious contribution from recombination of thermalized charm • Robust predictions require complete set of constraints from pp and pA.

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