The Quark Gluon Plasma at RHIC

1. The Quark Gluon Plasma at RHIC Colloquium Caltech Barbara V. Jacak Stony Brook Oct. 27, 2005

2. outline • What’s a plasma? • and why do we expect one from quarks and gluons? • The tools to make and study quark gluon plasma • What do we see at RHIC? • collective flow • opacity of the matter • excitations of the matter? • J/y suppression to search for deconfinement • Conclusions • what we have found • what HAVE we found?

3. what is a plasma? • 4th state of matter (after solid, liquid and gas) • a plasma is: • ionized gas which is macroscopically neutral • exhibits collective effects • interactions among charges of multiple particles • spreads charge out into characteristic (Debye) length, lD • multiple particles inside this length • they screen each other • plasma size > lD • “normal” plasmas are electromagnetic (e + ions) • quark-gluon plasma interacts via strong interaction • color forces rather than EM • exchanged particles: g instead of g

4. Quarks, gluons, hadrons • 6 quarks: • 2 light (u,d), 1 sort of light (s) • 2 heavy (c,b), 1very heavy (t) • flavor & color quantum numbers • Quarks are bound into hadrons • Baryons (e.g. n, p) have 3 • Mesons (e.g. p, K, f): 2 (q + anti-q) • Colored quarks interact by exchange of gluons • Quantum Chromo Dynamics (QCD) • Field theory of the strong interaction • parallels Quantum Electrodynamics (QED) • EM interactions: exchanged photons electrically uncharged • gluons carry color charge

5. At high temperature and density: force is screened by produced color-charges expect transition to gas of free quarks and gluons + +… QCD phase transition Color charge of gluons  gluons interact among themselves • theory is non-abelian • curious properties at large distance: • confinement of quarks in hadrons

6. Karsch, Laermann, Peikert ‘99 ~15% from ideal gas of weakly interacting quarks & gluons e/T4 T/Tc Tc ~ 170 ± 10 MeV (1012 °K) e ~ 3 GeV/fm3 non-perturbative QCD – lattice gauge theory required conditions to study quark gluon plasma

7. to get there: collide BIG ions at v ~ c • Create high(est!) energy density matter • similar to that existing ~1 msec after the Big Bang • can study only in the lab – relics from Big Bang inaccessible • T ~ 200-400 MeV (~ 2-4 x 1012 K) • e ~ 5-15 GeV/fm3 (~ 1030 J/cm2) • R ~ 10 fm, tlife ~ 10 fm/c (~3 x 10-23 sec) • Characterize the hot, dense medium • does medium behave as a plasma? coupling weak or strong? • What’s the density, temperature, radiation rate, collision frequency, conductivity, opacity, Debye screening length? • probes: passive (radiation) and those created in the collision

8. ideal gas or strongly coupled plasma? how does it compare to interesting EM plasmas? • Huge gluon density! • estimate G = <PE>/<KE> • using QCD coupling strength g • <PE>=g2/d d ~1/(41/3T) • <KE> ~ 3T • g2 ~ 4-6 (value runs with T) • G ~ g2 (41/3T)/ 3T so plasma parameter G ~ 3  quark gluon plasma should be a strongly coupled plasma • As in warm, dense plasma at lower (but still high) T G > 1: strongly coupled, few particles inside Debye radius

9. RHIC at Brookhaven National Laboratory Collide Au + Au ions for maximum volume s = 200 GeV/nucleon pair, p+p and d+A to compare

10. STAR 4 complementary experiments

11. p-p PRL 91 (2003) 241803 Good agreement with NLO pQCD Study simple complex systems: p+p, “p”+A, A+A collisions is QCD the right theory at RHIC? Perturbative for high p transfer processes?  pp collisions: itworks! Have a handle on initial NN interactions by scattering of q, g inside N p0

12. look at radiated & “probe” particles • as a function of transverse momentum • pT = p sin q • q with respect to beam direction • 90° is where the action is (max T, r) • midway between the two beams! • pT < 1.5 GeV/c • “thermal” particles from the bulk of the plasma • pT > 3 GeV/c • fast particles – mostly part of jets of hadrons coming from hard scattered q or g • produced very early, probe the plasma

13. z y x Almond shape overlap region in coordinate space search for collectivity (plasma feature) momentum space dN/df ~ 1 + 2 v2(pT) cos (2f) + … “elliptic flow”

14. Hydro. Calculations Huovinen, P. Kolb, U. Heinz Kolb, et al Hydrodynamics can reproduce magnitude of elliptic flow for p, p. BUT mass dependence → softer than hadronic EOS!! NB: these calculations have viscosity = 0 medium behaves as perfect liquid! v2 reproduced by hydrodynamics • see large pressure buildup! • anisotropy  happens fast • early equilibration STAR PRL 86 (2001) 402 central

15. 0 1 2 pT/n (GeV/c) • v2 scales ~ with # of quarks! • quarks are the particles when the pressure is built up Elliptic flow scales as number of quarks

16. even charm quarks flow! measure D→e± + hadrons Mcharm = 1.3 GeV D’s flow to ~2 GeV/c then expect e from B decays (Mb~4 GeV → shouldn’t flow) collective flows tell us: RHIC creates matter – not just collection of particles the matter catches even the heavy c quarks!

17. How to actively probe the deep interior? measure “hard scatterings”of q,g at large pT“transverse momenta” p pT q

18. Direct Photon Spectra in Au+Au • q + g → q + g • Should not interact with the color charges • data and theory agree → calibrated probe • pQCD works in the complex environment of two nuclei (Au+Au ) colliding at high energies

19. peripheral Ncoll = 12.3  4.0 central Ncoll = 975  94 strongly interacting probe: a different story!

20. suppression persists to 20 GeV/c! nuclear modification factor ratio of data on previous slide

21. so we see: photons shine, pions don’t • Direct photons are not inhibited by hot/dense medium • Pions (all hadrons) are inhibited by hot/dense medium

22. Medium is opaque! look for the jet on the other side STAR PRL 90, 082302 (2003) Peripheral Au + Au Central Au + Au

23. Pedestal&flow subtracted Are back-to-back jets there in d+Au? Yes!

24. QGP properties, so far • Extract from models, constrain by data Equation of state? Early degrees of freedom and their s? Deconfinement? Thermalization mechanism? Conductivity?

25. Lattice QCD shows qq resonant states at T > Tc, also implying high interaction cross sections How to get fast equilibration & large v2 ? parton cascade using free q,g scattering cross sections doesn’t work! need s x50 in medium

26. What is going on? • The objects colliding inside the plasma are not baryons and mesons • The objects colliding also do not seem to be quarks and gluons totally free of the influence of their neighbors • Quarks and gluons are interacting, but are not locally (color) neutral like the baryons & mesons. Neutrality scale likely larger, as expected for a plasma.

27. strongly coupled gas of atoms • M. Gehm, S. Granade, S. Hemmer, K, O’Hara, J. ThomasScience 298 2179 (2002) strongly coupled ↓ elliptic flow! weakly coupled

28. what about the heavier quarks? e± in Au+Au vs <Ncoll>*p+p peripheral collisions central collisions c quark suppression is nearly as large as for pions!

29. where does the lost energy go? • transferred to the plasma? • does the medium respond? • look at “away side” jet’s particles near thermal pT

30. STAR Preliminary (1/Ntrig)dN/d(Df) M.Miller, QM04 PHENIX dN/d(Df) 0 p/2 p p/2 p Df =+/-1.23=1.91,4.37 → cs ~ 0.33 (√0.33 in QGP, 0.2 in hadron gas) a sonic boom? jury is still out… g radiates energy kick particles in the plasma accelerate them along the jet

31. RHIC How about the screening length? • J/Y • Test confinement: • do bound c + c survive? • or does QGP screening kill them?

32. AtCERN (√s = 17 GeV): • NA50 and NA60 show suppression in Pb+Pb & In+In • suppression follows system size • Normal nuclear absorption from p+A data:  = 4.18±0.35 mb

33. At RHIC: J/ymm muon arm 1.2 < |y| < 2.2 measured/expected dAu mm 200 GeV/c AuAu mm 200 GeV/c CuCu mm 200 GeV/c

34. At RHIC: J/ymm muon arm 1.2 < |y| < 2.2 J/yee Central arm -0.35 < y < 0.35 dAu mm 200 GeV/c AuAu mm 200 GeV/c CuCu mm 200 GeV/c AuAu ee 200 GeV/c CuCu ee 200 GeV/c

35. At RHIC: J/ymm muon arm 1.2 < |y| < 2.2 J/yee Central arm -0.35 < y < 0.35 ! Factor ~3 suppression in central events dAu mm 200 GeV/c AuAu mm 200 GeV/c CuCu mm 200 GeV/c AuAu ee 200 GeV/c CuCu ee 200 GeV/c CuCu mm 62 GeV/c

36. At RHIC: J/ymm muon arm 1.2 < |y| < 2.2 J/yee Central arm -0.35 < y < 0.35 ! Factor ~3 suppression in central events Data show the same trend within errors for all beams and even at √s=62 GeV

37. RAA vs Npart: PHENIX and NA50 • NA50 data normalized at NA50 p+p point. • Suppression similar in the two experiments, although the collision energy is 10 times higher (200GeV in PHENIX & 17GeV in NA50)

38. What suppression should we expect? Models that were successful in describing SPS data fail to describe data at RHIC - too much suppression -

39. can get better agreement with data if add formation of “extra” J/y by coalescence of c and anti-c from the plasma (not necessarily unique or correct explanation!)

40. quarks & gluons retain correlations, medium exhibits liquid properties J/y may survive better NB: the (quasi-)bound states are not your mother’s hadrons! take a deep breath… • What did we expect for QGP? • What SHOULD we expect? weakly interacting gas of quarks & gluons

41. conclusions Evidence that RHIC creates a strongly coupled, opaque plasma energy density & equation of state not hadronic! must search for plasma phenomena, not asymptotic freedom • With aid of hydrodynamics, l-QCD and p-QCD models: • e ~ 15 GeV/fm3 • dNgluon/dy ~ 1000 • sint large for T < 2-3 Tc • can get at properties of this new kind of plasma • opacity, collision frequency, EOS, screening, speed of sound, conductivity • Open questions • Do heavy quarks really thermalize in the QGP? • Initial temperature (direct g radiation from plasma?) • Discovery announcement soon?

42. Energy  to beam direction per unit velocity || to beam pR2 2ct0 Is the energy density high enough? PRL87, 052301 (2001) Colliding system expands: • e 5.5 GeV/fm3 (200 GeV Au+Au) well above predicted transition! value is lower limit: longitudinal expansion rate, formation time overestimated

43. Does final state reflect a thermal distribution? Assume all distributions described by a temperature Tand a (baryon) chemical potential m: dn ~ e -(E-m)/T d3p One ratio (e.g., p / p ) determines m / T : pbar/p = e -(E+m)/T /e -(E-m)/T = e -2m/T Second ratio (e.g., K / p ) provides T  m;predict others Tf ~ 175 MeV

44. black holes at RHIC? • Not the usual ones that come to mind! • energy and particles get out (we see them) • rate of particle production scales from non-QGP producing collisions – so no evidence of eating ANY external mass/energy • This experiment has been done MANY times by nature • high energy cosmic rays impinging on atmosphere • Recent paper by Nastase uses mathematics of black holes developed by Hawking, but forces and behavior (and sizes) are quite different

45. Possibility of plasma instability → anisotropy • small deBroglie wavelength q,g point sources for g fields • gluon fields obey Maxwell’s equations • add initial anisotropy and you’d expect Weibel instability • moving charged particles induce B fields • B field traps soft particles moving in A direction • trapped particle’s current reinforces trapping B field • can get exponential growth • (e.g. causes filamentation of beams) • could also happen to gluon fields early in Au+Au collision • timescale short compared to QGP lifetime • but gluon-gluon interactions may cause instability to saturate → drives system to isotropy & thermalization

46. do heavy quarks thermalize? elliptic flow? energy loss!

47. r/ ggg d + Au collisions cent/periph. (~RAA) Saturation of gluons in initial state(colored glass condensate) Mueller, McLerran, Kharzeev, … Wavefunction of low x (very soft) gluons overlap and the self-coupling gluons fuse. Saturation at higher x at RHIC vs. HERA due to nuclear size  suppressed jet cross section; no back-back pairs

48. Open charm: baseline is p+p collisions PHENIX PRELIMINARY Measure charm s via semi-leptonic decay to e+ & e- p0, h, photon conversions are measured and subtracted fit p+p data to get the baseline for d+Au and Au+Au.

49. Implications of the results for QGP • Ample evidence for equilibration • initial dN(gluon)/dy ~ 1000, energy density ~ 15 GeV/fm3, energy loss ~ 7-10 GeV/fm • Very rapid, large pressure build up requires • parton interaction cross sections 50x perturbative s

50. How to get 50 times pQCD s? spectral function • Lattice indicates that hadrons don’t all melt at Tc! • hc bound at 1.5 Tc Asakawa & Hatsuda, PRL92, 012001 (2004) • charmonium bound states up to ~ 1.7 Tc Karsch; Asakawa&Hatsuda • p, s survive as resonances Schaefer & Shuryak, PLB 356 , 147(1995) • q,g have thermal masses at high T. as runs up at T>Tc? (Shuryak and Zahed) • would cause strong rescattering qq  meson