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Thermalization of the Quark-Gluon Plasma and Dynamical Formation of Bose Condensate

NN2012 @ San Antonio MAY.31 th , 2012. Thermalization of the Quark-Gluon Plasma and Dynamical Formation of Bose Condensate. Jinfeng Liao Indiana University, Physics Dept. & CEEM RIKEN BNL Research Center. Outline. The Pre-Equilibrium Matter in Heavy Ion Collisions

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Thermalization of the Quark-Gluon Plasma and Dynamical Formation of Bose Condensate

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  1. NN2012 @ San Antonio MAY.31th, 2012 Thermalization of the Quark-Gluon Plasmaand Dynamical Formation of Bose Condensate Jinfeng Liao Indiana University, Physics Dept. & CEEM RIKEN BNL Research Center

  2. Outline • The Pre-Equilibrium Matter in Heavy Ion Collisions • Important Features: Overpopulation & Uni-Scale • A Kinetic Approach: Dynamical BEC & Separation of Scales • Discussions References: Blaizot, Gelis, JL, McLerran, Venugopalan, Nucl. Phys. A873, 68 (2012); Blaizot, JL, McLerran, to appear; Chiu, Hemmick, Khachatryan, Leonidov, JL, McLerran, arXiv:1202.3679 [nucl-th].

  3. “Little Bang” in the Laboratories RHIC Event (from STAR) LHC Event (from ALICE) Currently ongoing heavy ion collisions programs: RHIC (BNL), since 2000; LHC (CERN), since 2010. Beautiful “little bang” delivered ! T~10^12 K : The hottest matter today! Furthermore: strongly interacting !

  4. Hot QCD Matter: Nearly Perfect Fluid Song, Bass, Heinz, Hirano, Shen, 2010 Created matter’s explosion appears nearly ideal  strongly coupled “Coupling-ometer” via transport properties e.g. shear viscosity Infinity (eta/s=1/4pi) (quantum limit?) 0 (infinitely viscous)

  5. Hot QCD Matter: Strong Jet Quenching Gyulassy, Wang; …… Jet-medium interaction is very strong color-opaque matter! (high Pt yield (Raa), di-hadron correlation,…… )

  6. Just After the “Little Bang”??? Heavy ion physics modeling (hydro, jet, …) implies a thermalized QGP already around 1 fm/c  fast thermalization, or strong re-scattering  Strongly interacting matter from the very beginning, but how? t = 0 t = 1fm/c • The energy/momentum scale, ~1 GeV, is still high here • A.F. says the coupling should be small/moderate ?! • However, the(phase-space) density is so high • that it coherently amplifies interaction •  More is different ! crucial for early time evolution!

  7. The Pre-Equilibrium Matter Strong constraint from the initial condition: saturation Pre-equilibrium matter (We focus on this!) Strong constraint from Hydro modeling and empirical data: fast “thermalization” ~ fm/c (to the extent of justifying hydro as effective description)

  8. The Pre-Pre-Equilibrium Before the collision: saturation Right after the collision Strong longitudinal expansion  anisotropy; Instabilities play an important role: Isotropization of energy-momentum tensor; rapid growth toward large occupation of soft modes; on the time scale ~ 1/Qs .

  9. A High Density Gluon System We consider a high density gluon system, starting at a time Our starting point Some idealization concerning real heavy ion collisions: very large transversely; very high energy , i.e. large Qs and small coupling Energy scale

  10. Far from Equilibrium… The initial gluon system is far from equilibrium ! (Plotted here: f(p) ) Initial gluon distribution Equilibrium Distribution (with the same Energy density) Saturation Scale Qs ~ 1 GeV or larger, weakly coupled Thermalization: how the initial distribution evolves toward the equilibrium?

  11. Three Important Features of the Initial System • Very high phase space density f ~ 1/alpha_s • Strong overpopulation • Only one scale that characterizes the distribution

  12. Amplified Scattering The initial gluon system is highly occupied  change the power-counting e.g. for the collision integral in kinetic evolution Coherent amplification of scattering  Fast thermalization from overpopulation?!

  13. Kinetic Evolution With 22 gluon scattering & small-angle approximation (Blaizot, JL, McLerran, to appear) (BE as fixed point) For highly occupied initial condition: coupling constant disappears in the scales! In contrast, for thermalized BE distribution:

  14. OVERPOPULATION We consider a high density gluon system, starting at a time Overpopulation parameter: For our initial gluon system: In contrast, for equilibrated QGP: For the given amount of energy, there are initially way too many gluons !

  15. OVERPOPULATION Does building up a chemical potential help? NO! The maximum gluons that can be accommodated by a Bose-Einstein distribution with \mu: • For the given amount of initial energy, our gluon system has too many gluons • Actually a “cold” dense system of gluons initially • can NOT equilibrate to a BE distribution by default (assuming elastic dominance)

  16. OVERPOPULATION Overpopulation  Bose-Einstein condensation for equilibrium state All the extra gluons get absorbed into zero momentum mode.

  17. Bose-Einstein Condensation from Overpopulation Initial overpopulation + Energy & Number conservation  BEC !! Atomic BEC: for given number of atoms, reduce energy (cooling) toward overpopulation Dynamical formation of BEC at the early stage after heavy ion collisions: born to have too many gluons for the available energy , really fascinating ! (Caveat: assuming elastic process dominance on certain time scale; discuss later…)

  18. Initially Uni-Scale There is ONLY ONE SCALE initially, i.e. the Qs This distribution is highly un-desired thermodynamically, i.e. by examining the entropy: Thermalization maximization of entropy More beneficial to distribute the gluons to wider region in p-space with f ~ 1

  19. Separation of Scales We introduce two scales --- momentum cutoff scale & the saturated scale There is ONLY ONE SCALE initially, Toward thermalization, the two scales must be separated! By how much? Again, for a very weakly coupled equilibrated QGP Thermalizationmust be accompanied byspecific separation of the two scales:

  20. Recap of the Scenario • A highly overpopulated gluon system evolving toward equilibrium: • High occupancy • coherent amplification of scattering, ~O(1) effect despite coupling • Strong overpopulation  dynamical BEC formation • Initial uni-scale  separation of the two scales by coupling \alpha_s NEXT: analytic analysis of scaling solutions ; ultimately nuermically solving the equation

  21. Kinetic Approach & Approximate Scaling Solution Blaizot, JL, McLerran, to appear.

  22. The “Static Box” Problem A schematic scaling distribution characterized by the two evolving scales: Time evolution of the distribution, i.e. of the two scales  need two conditions • Essential points here: • Energy is conserved, but not gluon number  absorption into condensate • Collision time scale (from transport equation) ~ \tau for scaling solutions

  23. Thermalization in The “Static Box” Two conditions fixing the time evolution: The scaling solution: Upon thermalization: separation of scales; entropy production; eliminating over-pop.

  24. Thermalization in The “Static Box” Two conditions fixing the time evolution: The scaling solution: Upon thermalization: separation of scales; entropy production; eliminating over-pop.

  25. Condensate in The “Static Box” Condensate dominates the number density: While gluons dominate the energy density A robust, though transient ultimately, Bose-Einstein condensate can be dynamically formed and maintained during the thermalization!

  26. Evidence of BEC from Scalar Field Theory Computation From: Epelbaum & Gelis

  27. Evidence of BEC from Scalar Field Theory Computation From: Berges & Sexty

  28. Effect of Longitudinal Expansion Assuming boost-invariance and studying mid-rapidity Further assuming certain fixed anisotropy

  29. Effect of Longitudinal Expansion Two conditions fixing the time evolution: The scaling solution: Upon thermalization: separation of scales; entropy production; eliminating over-pop.

  30. Condensate in Expanding Case NOTE: anisotropic expansion reduces overpopulation Condensate still can exist and dominate density: Energy carried by condensate is subleading: The more isotropic the expansion is, the stronger the condensation will be. Would be great to test in scalar/gauge field simulations aand kinetic computation.

  31. Summary: a Scenario for the First-Fermi/c after Little Bang • The pre-equilibrium matter starts with • high gluon density and one scale. • Elastic scattering is coherently enhanced despite the • small coupling, therefore leading to strongly interacting • matter even at early time and driving the thermalization. • Strong overpopulation enforces the system toward BEC. • Separation of scales must happen toward thermalization. • Expansion may proceed with asymmetry  anisotropic hydro?

  32. Post Summary: EM Production in the Pre-Equilibrium Matter There should be additional EM emission from the pre-equilibrium stage We derived fitting formula motivated by our thermalization scenario. DILEPTONS PHOTONS There are important contributions to EM production from the pre-equilibrium matter ! Chiu, Hemmick, Khachatryan, Leonidov, JL, McLerran, arXiv:1202.3679 [nucl-th].

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