Litcius/Paper detail

Revisiting shear stress tensor evolution: Nonresistive magnetohydrodynamics with momentum-dependent relaxation time

Sunny Kumar Singh, Manu Kurian, Vinod Chandra

2024Physical review. D/Physical review. D.11 citationsDOIOpen Access PDF

Abstract

This study aims to develop second-order relativistic viscous magnetohydrodynamics (MHD) derived from kinetic theory within an extended relaxation time approximation (momentum/energy dependent) for the collision kernel. The investigation involves a detailed examination of shear stress tensor evolution equations and associated transport coefficients. The Boltzmann equation is solved using a Chapman-Enskog-like gradient expansion for a charge-conserved conformal system, incorporating a momentum-dependent relaxation time. The derived relativistic nonresistive, viscous second-order MHD equations for the shear stress tensor reveal significant modifications in the coupling with dissipative charge current and magnetic field due to the momentum dependence of the relaxation time. By utilizing a power law parametrization to quantify the momentum dependence of the relaxation time, the anisotropic magnetic field-dependent shear coefficients in the Navier-Stokes limit have been investigated. The resulting viscous coefficients are seen to be sensitive to the momentum dependence of the relaxation time. Published by the American Physical Society 2024

Topics & Concepts

MagnetohydrodynamicsResistive touchscreenTensor (intrinsic definition)Cauchy stress tensorPhysicsViscous stress tensorShear (geology)Momentum (technical analysis)Time evolutionRelaxation (psychology)Classical mechanicsMechanicsMathematicsMaterials scienceQuantum mechanicsEconomicsGeometryComputer scienceMagnetic fieldPsychologyNeuroscienceFinanceComposite materialComputer visionGeomagnetism and Paleomagnetism StudiesSolar and Space Plasma DynamicsHigh-pressure geophysics and materials