Charm and bottom flavored hadrons production from strangeness rich quark gluon plasma hadronization Inga Kuznetsova and Johann Rafelski Department of Physics,

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Charm and bottom flavored hadrons production from strangeness rich quark gluon plasma hadronization Inga Kuznetsova and Johann Rafelski Department of Physics, University of Arizona Supported by a grant from the U.S. Department of energy, DE-FG02-04ER41318 We study QGP hadronization at given b, c quark content. We predict the yields of charm and bottom flavored hadrons within statistical hadronization model. The important new feature is that we take into account high strangeness and entropy content of QGP, conserving strangeness yield and entropy at hadronization. The European Physical Journal C - Particles and Fields. C51, , (2007) arXiv:hep-ph/

Motivations Probe of QGP properties, confirmation of deconfinement Information on hadronization temperature of heavy flavored hadrons Understanding of properties of phase transition between deconfinement phase and hadronic gas (HG) phase in strangeness rich QGP.

Statistical model Assumed Boltzman distribution for b, c, s, hadrons:  = T ln  for all particles γ i is phase space occupancy factor γ i =1, n i = n i eq is chemical equilibrium for particle i γ i Q is in QGP i=c, b, s, q (q is u or d) γ i H after hadronization, for example for D mesons: γ D H = γ c H γ q H where

Main model assumptions We do not assume chemical equilibrium for quark flavors. We work in framework of fast hadronization to final state. Physical conditions (system volume, temperature) do not change. Flavor conservation: fixes statistical parameters (γ b H, γ c H, γ s H ) for quark yield. Entropy conservation: fixes In QGP (The entropy of expanding QGP is conserved: ) For LHC:

Strangeness Strangeness (s) production in thermal gluon fusion follows in time entropy (S) production Ratio s/S depends on energy of collision, s increases faster with energy then S. The hot state, where the threshold for s production is exceeded, lives longer At RHIC energies s/S ~ 0.03, at LHC expect 0.03 ≤ s/S ≤ 0.05  obtained from SHARE 2.1 ``SHARE: Statistical hadronization with resonances,'' G. Torrieri, S. Steinke, W. Broniowski, W.Florkowski, J. Letessier and J. R, Comput. Phys. Commun. 167, 229 (2005) (SHARE 1) [arXiv:nucl-th/ ]; G.Torrieri, S.Jeon, J.Letessier and J. R, Comput. Phys. Commun. 175, 635 (2006) (SHARE 2) [arXiv:nucl-th/ ] Webpage: sharev1.html

Effect of strangeness on ratio D/D s. LHC?

Ratio D(B)/D s (B s ) as a probe of T at measured s/S Chemical equilibrium

Non-strange to strange charm baryons yields ratios as a function of γ s /γ q ratio LHC?

Double strange charm baryons (Ω c 0 ) yield as a function of hadronization temperature T Ω c 0 (2700 MeV) decay modes: Σ + K - K - π + Ξ 0 K - π + Ξ - K - π + π + Ω - π + Ω - π + π 0 Ω - π - π + π +

Total yield of all hidden charm mesons as a function of T.

J/Ψ yield as a function of γ s /γ q Both entropy and strangeness contents enhancement may result to J/Ψ suppression. More light and\or strange quarks more probability for charm to bound to these quarks than to find anti-charm quark.

Conclusions  Phase space occupancy factors of strange and light quarks have strong influence on heavy flavor hadron production.  Significant increase of the yield of strange quark-containing charm (bottom) mesons and baryons with increase of s/S as compared to the chemical equilibrium yields.  The change in the yield of hadrons without strangeness but with light quark(s) depends on both s/S and γ q. The ratio of these hadrons to similar strange hadrons always decreases with increase of s/S.  Yields of hadrons with two heavy quarks, as J/Ψ, decrease compared to chemical equilibrium when γ q and\or γ s > 1. This may provide a mechanism of J/Ψ suppression.

Entropy after hadronization Because of liberation of color degree of freedom The excess of entropy is observed in the multiplicity of particles in final state. After hadronizaton S Q ≈S H, γ q H >1. When γ q H = γ q cr : Bose singularity for pions; Maximum of possible entropy content after hadronization

Strangeness conservation during hadronization The equilibrium densities n i eq are sums of all known states densities for given particle i.

Charm (bottom) hadronization c,b quarks produced in first nn collisions. c=10, b=1; Flavor conservation equation γ b H >> γ c H >> γ s H Equilibrium case when γ q H = γ s H =1

D(B), Ds(Bs) mesons yield as a function of γ s /γ q. γ c(b) /N c(b) is almost independent from N c(b).