Author:
Glozman Leonid Ya.,Philipsen Owe,Pisarski Robert D.
Abstract
AbstractLattice QCD simulations with chirally symmetric quarks have recently established approximate $$SU(2)_{CS}$$
S
U
(
2
)
CS
and $$SU(2N_F)$$
S
U
(
2
N
F
)
symmetries of the quantum effective action in a temperature range above the chiral crossover $$T_\textrm{ch}$$
T
ch
, in which color-electric interactions between quarks dominate the dynamics. We show that such an intermediate temperature range between the chirally broken and plasma regimes is fully consistent with published screening mass spectra, which demonstrate the breakdown of thermal perturbation theory at the crossover between the partonic and the chiral spin symmetric regime at $$T_s\sim (2-3)T_\textrm{ch}$$
T
s
∼
(
2
-
3
)
T
ch
. From the known behavior of screening masses with baryon chemical potential, we deduce qualitatively how this chiral spin symmetric band extends into the QCD phase diagram. In the cold and dense region, we propose parity doubled baryons as possible candidates for chiral spin symmetric matter. This represents a special case of quarkyonic matter with confinement and restored chiral symmetry, and can smoothly transform to quark matter at sufficiently high densities. Finally, we discuss the potential of dilepton spectra to identify such matter forms.
Funder
Hessisches Ministerium für Wissenschaft und Kunst
Deutsche Forschungsgemeinschaft
Publisher
Springer Science and Business Media LLC
Subject
Nuclear and High Energy Physics
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