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1 The Quark Gluon Plasma and the Perfect Fluid Quantifying Degrees of Perfection Jamie Nagle University of Colorado, Boulder.

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Presentation on theme: "1 The Quark Gluon Plasma and the Perfect Fluid Quantifying Degrees of Perfection Jamie Nagle University of Colorado, Boulder."— Presentation transcript:

1 1 The Quark Gluon Plasma and the Perfect Fluid Quantifying Degrees of Perfection Jamie Nagle University of Colorado, Boulder

2 2 What do terms like “Quark Soup” and “Perfect Liquid” mean? How does that compare with a “Quark Gluon Plasma”? Good questions !

3 3 Quark Gluon Plasma

4 4 Can we melt the hadrons and liberate quark and gluon degrees of freedom? Energy density for “g” massless d.o.f. Hadronic Matter: quarks and gluons confined For T ~ 200 MeV, 3 pions with spin=0 Quark Gluon Matter: 8 gluons; 2 quark flavors, antiquarks, 2 spins, 3 colors 37 ! Degrees of Freedom

5 5 Lattice QCD Confirmation Temperature / T c  /T 4 And it reaches 80% of the non-interacting gas limit. QCD does reveal a transition (smooth cross over perhaps) with almost an order of magnitude change in the thermodynamic degrees of freedom.

6 6 “Freely Roaming” Quarks and Gluons? “Quarks and gluons freely roam within the volume of the fireball created by the collision.” This implies that thermodynamic degrees of freedom are associated with specific moving quasi-particles. Quasi-particle = collective medium excitation that has a width which is much smaller than its energy and acts like a ballistic particle Is this “freely roaming” picture right? 2000

7 7 Crank the Energy Up and Do the Experiment ! 10,000 virtual gluons, quarks, and antiquarks from the nuclear wavefunctions are made physical in the laboratory ! What is the nature of this ensemble of partons?

8 8 Relativistic Heavy Ion Collider online since 2000. Design Au+Au energy and luminosity achieved. All experiments successfully taking data Polarized proton proton (spin) program underway STAR RHIC is doing great !

9 9

10 10 Out of a maximum energy of 39.4 TeV in central Gold Gold reactions, 26 TeV is deposited in the fireball. Energy density is far above the expected transition point. 26 TeV Fireball !

11 11 0 fm/c 2 fm/c 7 fm/c >7 fm/c Diagram from Peter Steinberg Time Evolution

12 12  ,  0, K , K *0 (892), K s 0, , p, d,  0, , ,  ,  0, K , K *0 (892), K s 0, , p, d,  0, , , ,  *(1385), ,  ,  *(1385),  *(1520),  ±,  (+ antiparticles) (+ antiparticles) in equilibrium at T > 170 MeV What Happens to All That Energy?

13 13 How Does the Matter Behave? Simple answer is with a very high degree of collectivity.

14 14 First time hydrodynamics without any viscosity describes heavy ion reactions. *viscosity = resistance of liquid to shear forces (and hence to flow) Thermalization time t=0.6 fm/c and  =20 GeV/fm 3 Like a Perfect Liquid? v2 p T (GeV)

15 15 Hydrodynamics Assume early equilibration and initial geometry Equations of Motion Equation of State from lattice QCD

16 16 Liquid  Hadrons Previous hydrodynamics assumes Liquid  Hadrons Mapping knows nothing of hadron structure, only masses. This breaks down at higher p T !

17 17 Flow “Knows” Quark Content ! Fluid  QuasiParticles  Hadrons Evidence for fluid breaking up into quasiparticles with quantum numbers of quarks before hadrons. n q = number of valence quarks

18 18 What Does This Mean? PHENIX: “Scaling suggests that partonic collectivity dominates the transverse expansion dynamics.” STAR: “[Scaling indicates] a pre-hadronization state in which the flowing medium reflects quark degrees of freedom.” Not exactly. Inviscid fluids do not carry quasi-particles, almost by definition (they create viscosity). Thus, thermodynamic degrees of freedom do not correspond to ballistic quasi-particles during the “perfect fluid time.” However, as the fluid breaks down, it may be that quasi-particles are formed that have an anisotropy pattern. Then these quasi-particles hadronize and their anisotropy is imprinted on all hadrons.

19 19 String Theory ? What could this have to do with our physics? The Maldacena duality, know also as AdS/CFT correspondence, has opened a way to study the strong coupling limit using classical gravity where it is difficult even with lattice Quantum Chromodynamics. It has been postulated that there is a universal lower viscosity bound for all strongly coupled systems, as determined in this dual gravitational system.

20 20 Critical future goal to put the QCD data point on this plot. ? Universal Viscosity Bound

21 21 Probing the Matter Calibrated LASER Matter we want to study Calibrated Light Meter Calibrated Heat Source Take an out of equilibrium probe and see how it equilibrates !

22 22 Sometimes a high energy photon is created in the collision. We expect it to pass through the plasma without pause. Probes of the Medium Photons do not equilibrate with the matter.

23 23 Sometimes we produce a high energy quark or gluon. If the plasma is dense enough we expect the quark or gluon to be swallowed up. Probes of the Medium Quarks and Gluons do approach equilibration. Can we determine a transport coefficient q? ^

24 24 (from quark and gluon jets) Scaling of photons shows excellent calibrated probe. Quarks and gluons disappear into medium, except consistent with surface emission. Survival Probability Size of Medium Experimental Results

25 25 Constraint on Transport Coefficient Future running and RHIC II luminosities will give a precision measure of the transport coefficient. A major goal is to make such a constraint on other properties like  /s as detailed before.

26 26 Alternative: Put a pebble (or rock) in the stream….and watch something out of equilibrium then equilibrate. Need 3-d relativistic viscous hydrodynamics to compare to bulk medium flow. Significant theory milestone! How to Quantify  /s? Charm Quark Beauty Quark Perfect Fluid?

27 27 Charm Quark Probes Teaney and Moore Very large interactions suppress high p T and induce large flow. Suppression FactorFlow

28 28 Constraining  /s Rapp and van Hees Phys.Rev.C71:034907,2005 Phys.Rev.C71:034907,2005 –Simultaneously describe R AA (E) and v 2 (e) with diffusion coefficient in range D HQ (2  T) ~4-6 Moore and Teaney Phys.Rev.C71:064904,2005 Phys.Rev.C71:064904,2005 –Find D HQ /(  /(  +p)) ~ 6 for N f =3 Combining –  +p = T s at  B =0 –This then gives  /s ~(1.33-2)/ 4  Within a factor of 2 of the bound. Need separation of c and b to pin this down better.

29 29 Jet correlations in proton-proton reactions. Strong back-to- back peaks. Jet correlations in central Gold-Gold. Away side jet disappears for particles p T > 2 GeV Jet correlations in central Gold-Gold. Away side jet reappears for particles p T >200 MeV Azimuthal Angular Correlations Jet Quenching !

30 30 Where Does the Energy Go?

31 31 How does the near perfect liquid react to this large energy deposition? Color shock wave? Reaction of the Medium Sensitive to –Speed of sound –Equation of state

32 32 Conclusions RHIC program is operating very successfully. The Quark-Gluon Plasma as “freely roaming” quasi-particles carrying the degrees of freedom unlikely at early stages. Near Perfect Liquid Discovered. Challenge is now to quantify and understand its properties. Exciting future program at RHIC II and at the LHC. Perfect Liquid?


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