On interpretation of fluctuations of conserved charges at high T

Abstract

Fluctuations of conserved charges calculated on the lattice which can be measured experimentally, are well reproduced by a hadron resonanse gas model at temperatures below Tch ~ 155 MeV and radically deviate from the hadron resonance gas predictions above the chiral restoration crossover. This behavior is typically interpreted as an indication of deconfinement in the quark-gluon plasma regime. We present an argument that this interpretation may be too simple. The argument is based on the scaling of quantities with the number of colors: demonstration of deconfinement and QGP requires observable that is sensitive to Nc2 gluons while the conserved charges are sensitive only to quarks and above Tch scale as Nc1. The latter scaling is consistent with the existence of an intermediate regime characterized by restored chiral symmetry and by approximate chiral spin symmetry which is a symmetry of confining interaction. In this regime the energy density, pressure and entropy density scale as Nc1. In the large Nc limit this regime might become a distinct phase separated from the hadron gas and from QGP by phase transitions. A natural observable that associates with deconfinement and is directly sensitive to deconfined Nc2-1 gluons is the Polyakov loop; in the Nc=3 world it remains very close to 0 at temperatures well above chiral crossover, reaches the value 0.5 around 3Tch and the value close to 1 at temperatures ~1 GeV.