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The Physics of high baryon densities

and not so high. The Physics of high baryon densities. Probing the QCD phase diagram The critical end point Properties of mesons in matter Baryon density vs. temperature Probing cold dense matter Conclusions. B. Friman, GSI. Critical endpoint. C o l o u r superconductor.

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The Physics of high baryon densities

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  1. and not so high The Physics of high baryondensities • Probing the QCD phase diagram • The critical end point • Properties of mesons in matter • Baryon density vs. temperature • Probing cold dense matter • Conclusions B. Friman, GSI

  2. Critical endpoint Colour superconductor The QCD phase diagram Early universe Neutron stars: -low T -high B -strangeness -quark matter (CSC ?) T Quark-Gluon Plasma Meson dominated Chiral symmetry restored Hadronic matter Baryon dominated Chiral symmetry broken B Nuclei Neutron stars

  3. Critical endpoint Need: LHC RHIC SPS High, low and intermediate energies AGS Colour superconductor Different reactions AB, pA, A.. SIS The QCD phase diagram T Quark-Gluon Plasma Chiral symmetry restored Hadronic matter Chiral symmetry broken B Nuclei

  4. The critical end point Ejiri et al. Fodor-Katz Ejiri et al. (Bielefeld-Swansea): Bc 420 MeV Critical point expected to move to smaller B for realistic mq E  40 AGeV Fodor & Katz: Tc  160 MeV, Bc 720 MeV Adiabatic extrapolation to freeze-out curve:E ~ 10 AGeV

  5. Signatures of the critical end point? Quark number susceptibility Critical point:fluctuations of the order parameter are soft Look for rise and fall of fluctuations! (E-by-E) (Stephanov, Rajagopal, Shuryak) • E-by-E fluctuations of: • transverse momentum (SRS) • pion multiplicity (SRS) • proton number (Hatta, Stephanov) • . . . . . Ejiri et al. Take care of finite time and finite size effects (Berdnikov, Rajagopal) So far no convincing experimental evidence for the nuclear matter gas-liquid critical point Exciting prospects, but still many unknowns!

  6. 1800 |K+> = |us> |K-> = |su> Mass Overall attraction due to scalar interaction: KN sigma term K+ K- 500 Mass splitting due to vector interaction: Weinberg-Tomozawa  0 Effects of baryon density Mass splittings because charge conjugation symmetry broken at nB 0 K+ ~100 MeV K- 0 Easier to produce K- in dense matter

  7. Kaon production near threshold KaoS & FOPI @ GSI Ni+Ni (1.93 GeV) Repulsive potential Suppression of K+ Attractive potential Enhancement of K- Calculation: Cassing & Bratkovskaya

  8. Effects of baryon density (2) D+ D- D- 1800 ~50 MeV |D-> = |dc> D+ Mass |D+> = |cd> K+ K+ K- 500 ~100 MeV K-  0 0 D-Meson mass splitting at nB 0 Explore D-meson properties in dense matter at energies around charm threshold E  10-20 AGeV

  9. Chiral partners of D-mesons? cs-system cu-system CLEO(2003) Belle (2003) BaBar (2003) D(2427) Ds(2463) Ds(2317) D(2308) (1+) (1+) (0+) (0+) 1- ~Mq 0- u s c c Ds*(2112) Ds(1969) Chiral mass shifts  420 MeV (constituent quark mass) Chiral mass shifts  350 MeV Ds(0+) D(0-) + K Ds(0+) Ds(0-) +  D(0+) D(0-) +  / • D-mesons: • heavy-light system • hydrogen atom of QCD 1- 0- D*(2010) ~1/mQ D(1869) Light-quark-cloud probes chiral symmetry Heavy-quark-symmetry + chiral symmetry: chiral doubling of D-mesons (Nowak-Rho-Zahed and Bardeen-Hill, 92-93)

  10. Restoration of Chiral Symmetry at non-zero baryon density and temperature Chiralpartners become degenerate Explore dependence of hadron properties on quark condensate Role of chiral symmetry for hadron masses?

  11. D mesons in matter qq qq0 If chiral doubling scenario for D mesons correct then m(0+)-m(0-)  0 etc. as qq0 (chiral limit) m(0+)-m(0-) Harada, Rho, Sasaki (2003) 0 D-meson production in nuclear collisions offer a unique opportunity to explore chiral dynamics in dense matter

  12. f N N h M.Lutz G.Wolf B.F. N  N Beyond mean-field approximation Spectral functions change due to interactions Low-density expansion: Resonances in scattering amplitude: peaks in spectral function

  13. Baryon density vs. temperature R.Rapp Baryon dominated matter: meson spectral functions determined by baryon resonances Meson dominated matter: meson spectral functions determined by meson resonances Meson mixing atB  0 Resonances smeared by collision broadening These effects must be unfolded before one can draw conclusions on chiral symmetry and masses Need high resolution, high statistics data at a wide range of energies (T vs. B)

  14. Wroblewski factor: Peak ~ 30 AGeV Decrease: B 0 AGS K = B/3 - S NA49 RHIC  = 2 B/3 + S Sharp maximum in K+/+ Not understood! Strangeness and baryon density Rise: threshold dynamics Braun-Munzinger,Cleymans, Oeschler and Redlich No peak for B = 0!

  15. Complementary information from p A, p A,  A,  A … Probing cold dense matter in nuclei

  16.  + A  + X 0  Photo induced ωproduction Measured at ELSA by TAPS collaboration Data analysis in progress Simulation by Meschendorp et al. Assume at  = 0: m660 MeV, 60 MeV

  17. Summary • Critical endpoint: fluctuations • Light-heavy mesons: mass splitting • Chiral partners become degenerate • New D mesons • Data at different energies/different B/T • useful for unravelingmeson/baryon • resonances, meson mixing etc. • pA, A, A etc. provide complementary • information

  18. Some of these issues are being addressed at CERN SPS. Most of them can be explored at the GSI Future Facility Protons E 90 GeV Heavy ions (N=Z) E  45 AGeV Pb E 35 AGeV Stored antiprotonsE15 GeV Comprehensive heavy-ion program with strangeness, charm, lepton pairs and photons

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