Hydrodynamics of the Chiral Dirac Spectrum
arXiv:1506.08787 · doi:10.1016/j.physletb.2015.12.032
Abstract
We derive a hydrodynamical description of the eigenvalues of the chiral Dirac spectrum in the vacuum and in the large $N$ (volume) limit. The linearized hydrodynamics supports sound waves. The stochastic relaxation of the eigenvalues is captured by a hydrodynamical instanton configuration which follows from a pertinent form of Euler equation. The relaxation from a phase of localized eigenvalues and unbroken chiral symmetry to a phase of de-localized eigenvalues and broken chiral symmetry occurs over a time set by the speed of sound. We show that the time is $ÎÏ=ÏÏ(0)/2βN$ with $Ï(0)$ the spectral density at zero virtuality and $β=1,2,4$ for the three Dyson ensembles that characterize QCD with different quark representations in the ergodic regime.
6 pages