Transport coefficients enhanced by suprathermal particles in nonequilibrium heliospheric plasmas

TL;DR

This paper improves the evaluation of transport coefficients in heliospheric plasmas by incorporating suprathermal particles modeled with Kappa distributions, revealing significant enhancements in these coefficients.

Contribution

It introduces a novel approach using the Kappa distribution to quantify the impact of suprathermal particles on transport coefficients in space plasmas.

Findings

Transport coefficients are significantly enhanced by suprathermal electrons.

Kappa distribution effectively models the influence of suprathermal populations.

Results highlight the importance of accurate Kappa modeling for plasma transport analysis.

Abstract

In heliospheric plasmas the transport of energy and particles is governed by various fluxes (e.g., heat flux) triggered by different forces, electromagnetic fields, and gradients in density or temperature. In the outer corona and at relatively low heliocentric distances in the solar wind (i.e., < 1 AU), particle-particle collisions play an important role in the transport of energy, momentum, and matter, described within classical transport theory by the transport coefficients, which relate the fluxes to their sources. The present paper aims to improve the evaluation of the main transport coefficients in such nonequilibrium plasmas, on the basis of an implicit realistic characterization of their particle velocity distributions, in accord with the in situ observations. Of particular interest is the presence of suprathermal populations and their influence on these transport coefficients. Using the Boltzmann transport equation and macroscopic laws for the energy and particle fluxes, we derived electric conductivity, thermoelectric coefficient, thermal conductivity, diffusion, and mobility coefficient. These are conditioned by the electrons, which are empirically well described by the Kappa distribution, with a nearly Maxwellian core and power-law tails enhanced by the suprathermal population. Here we have adopted the original Kappa approach that has the ability to outline and quantify the contribution of suprathermal populations. Without exception, the transport coefficients are found to be systematically and markedly enhanced in the presence of suprathermal electrons, due to the additional kinetic energy with which these populations contribute to the dynamics of space plasma systems. The present results also show how important an adequate Kappa modeling of suprathermal populations is, which is in contrast to other modified interpretations that underestimate the effects of these populations.