Anisotropic modifications to the transport phenomena and observables in a hot QCD medium at finite baryon asymmetry

TL;DR

This paper investigates how weak momentum anisotropy from baryon asymmetry affects charge and heat transport in a hot QCD medium, revealing anisotropy reduces conductivities and alters flow correlations.

Contribution

It introduces a detailed kinetic theory analysis of anisotropic effects on transport properties in baryon asymmetric hot QCD matter, incorporating quasiparticle interactions.

Findings

Electrical and thermal conductivities decrease with anisotropy.

Baryon asymmetric matter shows larger conductivities than baryonless matter.

Anisotropy influences heat-charge flow correlation and modifies equilibrium properties.

Abstract

We have studied how the transport of charge and heat as well as associated observables become influenced by a weak-momentum anisotropy arising due to the asymptotic expansion of baryon asymmetric matter in the initial stages of heavy ion collisions. This study facilitates the understanding of the local equilibrium property of the medium through the Knudsen number, and explores the correlation between the heat flow and the charge flow through the Lorenz number in the Wiedemann-Franz law for an anisotropic hot QCD medium at finite baryon asymmetry. We have determined the electrical and the thermal conductivities by solving the relativistic Boltzmann transport equation in the relaxation time approximation within the kinetic theory approach. The interactions among partons are appended through their distribution functions within the quasiparticle model of the hot QCD medium at finite temperature, anisotropy and baryon asymmetry. We have observed a decrease in both electrical and thermal conductivities in the presence of expansion-induced anisotropy for baryonless scenario as well as for baryon asymmetric scenario. Conversely, these conductivities are found to be larger in the baryon asymmetric matter as compared to their counterparts in the baryonless matter. The impact of anisotropy on the baryon asymmetric matter is as conspicuous as on the baryonless matter. The above results are attributed to the squeezing of the distribution function due to the momentum anisotropy generated by the asymptotic expansion of baryon asymmetric matter and the dispersion relations of partons in the presence of anisotropy. Additionally, the aforesaid observables are also modulated by the expansion-induced anisotropy in the baryon asymmetric medium, indicating new predictions for the equilibrium characteristic and the relative behavior between the heat and charge flow for the said medium.