QCD Phase Diagram and Critical Point

1. QCD Phase Diagram and Critical Point Lecture at 5th CBM India CollaborationMeeting, BHU, Varanasi, IndiaDecember 28, 2009 Reviews: C.P. Singh, Phys. Rep. 236,147(1993) Int. J. Mod Phys. A7, 7185 (1992)

2. Outlines :1. Introduction2. History of QCD Phase Transition.3. QCD phase transition and Critical Point.4. Summary.

3. What happens to a matter at extremely large temperature and/or density 1 Nucleons/ Atomic matter Present Universe Nuclear matter Energy density Compare (if = 0.8 fm)

4. QCD – Lagrangian density Confinement Asymptotic freedom Continued….

5. QCD Two Important features = 0.2 GeV/c(1)Confinement→ Infra red slavery or (2)Asymptotic freedomQCD, the theory of strongly interacting matter, predicts that, above a critical energy density, hadrons, the constituents or normal nuclear matter, decompose into a plasma of quarks and gluons, the Quark Gluon Plasma, QGP. Sucha state existed shortly after the Big Bang and may exist as well in the neutron stars. Colliding heavy ions at extreme energies is the only way to study QGP on Earth.

6. QCD QED Debye screened confining Bound statescreened r At large T and large ρ r D is small ( r D < r) and thus Hadrons→ melt down Hadrons→ QGP

7. Phase Diagram of H2O P Cross-over region Water C1 Ice Critical Point Steam C2 Tri Critical point T C2 ( TC= 273.16 0K , PC= 600 N / m2 ) C1 ( TC= 647 0K , PC= 2.21x !07 N / m2 ) Ist order Discontinuity in S, V II order Discontinuity in CP, KT

8. Hadrons - Hadrons are colour insulators. - Force decreases with separation. - Dilute and low density matter. QGP - Quarks and gluons are coloured matter. - Force increases with separation. - Large density matter. QCD predicts a colour deconfining Phase transition

9. HISTORY OF QCD PHASE TRANSITION

11. - Baym (1982)

12. Order of Phase transition F = Free energy of the system discontinuous then it is nth order phase transition. 1st order = Latent Heat QGP 1st order HG SYMMETRIC 2nd order Broken symmetry T

13. Phase transition between H.G. (Pion Gas) QGP 1st order phase transition Maxwell’s construction If P T -B

14. TWO QCD VACUABag Model:Perturbative QCD vacuum (High T) Real or Physical QCD vacuum (Low T) Confinement pressure B Stress arising due to K.E. of quarks

16. QGP in two situationsTemperature T Measures the mean energy of the system.Baryon chemical potential measures the mean number of baryons in the system. Heat ---------------> dense inmesons T > 200 MeVEarly Universe (second after Big Bang)Baryons Mesons

17. Compress dense in Baryons ( Core of neutron star)

18. Chiral Symmetry Restoration Global flavour rotations matrix So rotation group is Chiral group 2 (2) (2) Flavour + rotations

19. Noether Current if 0 Chiral Symmetry Restoring Phase Transition This is non zero(250 MeV)3

20. Helicity of the quark is fixed (gluon interaction does not change the helicity ). BL & BR both are good quantum numbers. Quark can exist in both the helicities. B= BL + BR is a good quantum number. chiral symmetry is broken ( left and right quarks are not Independent ). pairs The vacuum contains ≈ (250 MeV)3 = Rate at which quarks flip their helicity.

21. T > TC Order parameter => = large T < TC T < TC Confinement => = 1 T > TC Susceptibilities

22. Courtesy : K. Fukushima, Feb 2008, QM08

23. Courtesy : K. Fukushima, Feb 2008, QM08

24. Courtesy : K. Fukushima, Feb 2008, QM08

25. LATTICE GAUGE THEORY • A numerical simulation of finite temperature QCD. • Entire range of strong interaction thermal dynamics. Main Features • We make space-time discrete and lattice if points with finite spacing a 0 gives continuous limit. We have lattice of sites. and V = T = • Divergences due to small (infra-red) and large (ultra-violet) momenta disappear. • = plaquette = square in space-time grid

26. matter fields as site variables = Link variable between adjacent sites Wilson Loop Order Parameter

27. Results: • No quarks Only gluons : 1st order • 3 or 4 massless quarks : 1st order • 2 massless quarks Continuous • 2 massless, non zero Continuous • Now calculations started with on the lattice Action

30. QCD Phase Diagram Reference :QCD Phase Boundary and Critical Point in a Bag Model Calculation C. P. Singh, P. K. Srivastava, S. K. Tiwari, Physical Review D (Accepted) QGP Equation Of State - where Here we have used B1/4=216 MeV and Λ =100 MeV. Hadron Gas Equation Of State - The Grand canonical partition function using full statistics and including excluded volume correction in a thermodynamically consistent manner -

31. Where g i is the degeneracy factor of ith species of baryon, E is the energy of the particle V0i is the eigen volume of one ith species of baryon and is the total volume occupied We can write above equation as - Where Is the fugacity of the particle, nexi is the number density of jth type of baryons after excluded volume correction. and

32. Using the basic thermodynamical relation between number density and partition function We can write as - Where Is the fractional volume occupied. We can write R in an opera- -tor equation - Where with And the operator Using Neumann iteration method, we get - Solving this equation numerically, we can get the total pressure of hadron gas after Excluded volume correction is - To draw the Phase diagram we uses the Gibbs’ equilibrium condition of phase transition -

33. New and Interesting Features : By Maxwell construction, it gives first order phase transition : PH (Tc,µC) = PQ (Tc,µC) (2) In cross over region, PQ > PH (3) End point of first order line is critical point (4) Our EOS for HG is thermodynamically consistent nB=∂PH/ ∂µB (5) Freeze out curve from HG description. (6) We have used full quantum statistics so we cover entire (T, µB) plane (7) We have used QGP EOS in which perturbative corrections have been added and non perturbative term includes Bag constant B0

34. Chemical Freeze out points : By fitting the hadron multiplicities at different energy

35. Color Flavour Locked ( CFL) Phase : Fermi degenerate matter: For quarks so Neutron star densities At Fermi surface -> qq interaction is weakly attractive ( Single gluon exchange) Results into BCS pairing instability diquark condensate <qq> ≠ 0

36. 2 Δ = energy gap between highest occupied and lowest vacant one particle state E Analogous to BCS cooper pair condensate in Superconductor 2 Δ Δ 10 -100 MeV EF k ≠ 0 a, b = 1,2 α, β =1,..3 K. Rajagopal Not colour neutral Colour Superconductivity no true phase transition between SC and QGP Color Flavour Locked phase If Gluon mass ~ Δ Superfluidity  Chiral Symmetry is broken, B  is not a good Q. No.

38. Critical point predicted by our new model

39. LTE04 LR04 LTE03 LR01 Chemical freeze out points Critical point by Our new Model Critical point by different NJL Models Critical point by different Lattice Model NJL/inst NJL NJL/II NJL/I

40. New Findings : We show the presence of cross-over region and precise location of critical point TC= 160 MeV, µC= 156 MeV (2) Entire conjectured phase boundary has been reproduced (3) We get a first order deconfining phase transition (4) Chemical Freeze out curve lies in close proximity to the critical point

41. Steps in space –time picture of nucleus-nucleus collisions: Pre equilibrium stageAt (z,t) =(0,0), nuclei collides and pass through each other, nucleons interact with each other. Formation stage Quarks and gluons (qq,gg) are produced in the central region a large amount of energy is deposited. Equlibration Due to parton interaction plasma evolves from formation stage to a thermalized QGP. Hadronization Thermalized plasma expands and cools until hadronization takes place and mesons and baryons are created. Freeze-out When temperature falls further, the hadrons no longer interact and they stream out of the collision region towards the detectors.

42. Signatures of QGP: • HGHot,dense hadron gas ( Background) QGP Quark Gluon matter with a collective behaviour. How to eliminate background contributions. • Lack of proper understanding of ultra relativistic Nuclear collisions: a. Thermal statistical model b. Superposition of hadron-hadron scattering. c. Transport theory Non equilibrium.

43. Signals of QGP 1. Dilepton production Thermometers Production rates and momentum distribution of these particles depend on the momentum distribution of the quarks and antiquarks in the plasma. Background contributions are Drell-Yann processes. Effects Mass and widths of resonances can shift in QGP ( e.g. , etc) 2. J/ suppressionJ/ is produced in pre equilibrium stage. c and c cannot be thermally produced in QGP. J/ while passing through the deconfining QGP medium, dissociates into c c pair which separate from each other and there is less probability that they can combine with each other to form J/ after QGP. A-A collisions J/ QGP J/ formation less likely Pre-equilibrium cc separates A-A J/ HG J/ less in number absorption or Rescattering

44. 3.Strangeness enhancement • For Baryon dense matter 300 MeV 150 MeV

45. Reference : M. Mishra and C. P. Singh Phys. Rev. C 78, 024910 (2008)

46. Baryon free QGP T >> = • Lower threshold ss 300 MeV (QGP) KK 1000 MeV (HG) d) gg ss facilitates strangeness in QGP After hadronization of QGP, ratio of particles like etc is large. 4. Jet Quenching In p p collisions, back to back two jets are produced. But when jet pass through the dense quark medium, one jet is more quenched and this effect is seen at RHIC.

47. 5. HBT Interferometry: When all the interactions are stopped, still Bose Einstein attraction or Fermi Dirac repulsion between a pair of particles always exist. Interference in coincident detectors Correlation C( , ) = = Fourier transform of freeze-out density = Large radii large volume at thermal freeze-out Signals of 1st order phase transition

49. Experimental Status 1987-1999: Brookhaven National Lab : AGSSi, Au beams were accelerated to 14.6 GeV/A CERN SPSS and Pb beams upto 200 GeV/A Inference Colliding nuclei are stopped Fireball Large number of produced particles which cannot be obtained by simple superposition of p-p collisions. 2000: BNL RHICCollider Experiments (Au-Au at 200 GeV/A)

50. SUMMARY - JET QUENCHING has been observed . - J/ suppression. - Large enhancement of strangeness. - HBT a large freezeout volume. - A perfect liquid with zero viscosity.