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Quarkyonic Phase and the QCD Phase Diagram : HIC-II. T. A-A collisions fixed. Early universe. A new view and on the QCD phase diagram Recent Lattice Gauge Theory results Quarkyonic phase & TRIPLE POINT in HIC. Quark-Gluon Plasma. Chiral symmetry

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  1. Quarkyonic Phase and the QCD Phase Diagram: HIC-II T A-A collisions fixed Early universe • A new view and on the QCD phase diagram • Recent Lattice Gauge Theory • results • Quarkyonic phase & • TRIPLE POINT in HIC Quark-Gluon Plasma Chiral symmetry restored Hadronic matter Chiral symmetry broken x B 1st principle calculations: perturbation theory pQCD LGT

  2. QCD thermodynamics in effective models • Models based on same symmetries as QCD : • chiral with order parameter • center with order parameter • due to universality one expects similar critical • properties • Approach based on the Schwinger-DysonEquation • Use Ads/QCD correspondence to gain information on QCD medium properties?

  3. GenericPhase diagram from effective chiral Lagrangians then (Pisarski-Wilczek) O(4)/O(2) univ.; see LGT , Eijri et al 09 • The existence and position of CP and transition is model and parameter dependent !! • Introducing di-quarks and their interactions with quark condensate results in CSC phase and dependently on the strength of interactions to new CP’s crossover 2nd order, Z(2) (Stephanov et al.) CP Asakawa-Yazaki 1st order Alford et al. Shuryak et al. Rajagopal et al. Hatsuda et al. Zhang et al, Kitazawa et al., Hatta, Ikeda; Fukushima et al., Ratti et al., Sasaki et al., Blaschke et al., Hell et al., Roessner et al., ..

  4. Probing CP with charge fluctuations • Net quark-number ,isovector and electric charge fluctuations CP The CP ( ) and TCP ( ) are the only points where the baryon number and electric charge densities diverge! A non-monotonic behaviour of charge density fluctuations are excellent probes of the CP

  5. Sasaki, Friman et al. 07

  6. Finite baryon density LGT in 2+1 f and CEP Fodor & Katz 04: multi-parameter rewighting F. Karsch at al. 07 T [MeV] [MeV] Det M through Taylor expansion method: Study radius of convergence and fluctuations to identify CP; No strong evidence of CP till now Det M exactly included in calculations Use the Lee-Yang theorem to identify CP See also: S. Ejiri 08

  7. LGT EOS at finite T and vanishing baryon density A. Bazavov et al. hotQCD Coll. 09 Asymptoticaly: 1. Kurtosis an excellent probe of deconfinement and chiral dynamics: A cusp-structure at for small expected from O(2) scaling Abrupt but smooth change of energy density indicates crossover transition : Results still not free from finite size effects!

  8. Finite Size Effects in LGT Thermodynamics hotQCD Coll. 07 8 Y. Aoki et al. 09 T>0 Different critical temperatures: Y. Aoki et al 09 hotQCD Coll. 07 Thermodynamics from p4fat action with is still calculated with non- physical mass spectrum;

  9. Thermodynamics in LGT with Highly Improved Staggered Quarks (HISQ) A. Bazavov1 & P. Petreczky, HotQCD Coll. 09 Tendency of shifting the transition region to lower temperatures than in previous asqtad and p4 studies on lattice !

  10. Novel Phase of QCD in the limit “ Quarkyonic Phase “ L. McLerran & R. Pisarski 07-09 Quarks O( ) Gluons O( ) “quark-yonic” : L. McLerran, C. Sasaki and K.R. 09 M. Harada, C. Sasaki, S. Takemoto 09 Quarkyonic phase can persists for

  11. Deconfinemnet at finite number of color At finite quarks destroy 1st order deconfinement phase transition to cross-over

  12. Quarkionic Phase (QP) in models with Polyakov Loop extended NJL model (PNJL) L. McLerran, C. Sasaki & K.R. 09 T [GeV] M. Harada, C. Sasaki, S. Takemoto 09 Quarkionic QP Quarkyonic Order parameter of sym. The Quarkionic Phase can persists for , thus could be also there in QCD? Order parameter of chiral symmetry restoration

  13. Probing the QCD Phase Boundary in HIC L. McLerran, R. Pisarski et al. Meson dominant Baryon dominant CP Freezeout line provide lower bound of the QCD phase boundary with clear separation of baryonic and mesonic dominance at Possible phase diagram of QCD with “Triple Point” and Quarkyonic Phase

  14. A. Andronic, P. Braun-Munzinger, J. Stachel 09 Particle ratios in HIC from SIS to RHIC An abrupt change in excitation functions of particle ratios at [GeV] change of production dynamics from quarkyonic ( etc.) to partonic via hadronization of the QGP? Quarkyonic Phase and HIC: Andronic,Blaschke, Braun-Munzinger, Cleymans, Fukushima, McLerran, Oeschler, Pisarski, Redlich, Sasaki, Satz, ,Stachel arXiv:0911.4806

  15. HBT & Freezeout volume Minimum of HBT and freezeout Volume at energies where Triple Point is expected to appear in QCD phase diagram

  16. Summary • Effective chiral models provide a powerful tool to study the critical consequences of the chiral symmetry restoration and deconfinement in QCD, however to quantify the QCD phase diagram and thermodynamics requires the first principle LGT calculations New results from LGT constrain the critical temperature at vanishing density to be < 170 MeV New phase diagram of QCD with Quarkyonic Phase results in Triple Point where three phases Hadronic Matter, Quarkyonic Matter, and a Quark-Gluon Plasma meet. Some properties of HIC data are consistent with existence of such Triple Point: Physics for FAIR & NICA to develope

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