Thermodynamics of the inner heliosheath

TL;DR

This study analyzes the thermodynamic properties of the inner heliosheath over several years using Interstellar Boundary Explorer data, revealing key relationships between temperature, density, kappa, and entropy, and introducing a new invariant quantity.

Contribution

The paper introduces a new invariant polytropic quantity {a0} and links kappa distributions with polytropic models to better understand IHS thermodynamics.

Findings

Temperature peaks in 2015 and dips in 2012.

Temperature inversely related to density, indicating subisothermal behavior.

Positive correlation between temperature and kappa, and entropy with polytropic index.

Abstract

We derive annual skymaps of the proton temperature in the inner heliosheath (IHS), and track their temporal evolution over the years from 2009 to 2016 of Interstellar Boundary Explorer observations. Other associated thermodynamic parameters also determined are the density, kappa, that is, the parameter that characterizes kappa distributions, temperature rate, polytropic index, and entropy. We exploit the theory of kappa distributions and their connection with polytropes, to (i) express a new polytropic quantity {\Pi} that remains invariant along streamlines where temperature and density may vary, (ii) parameterize the proton flux in terms of the {\Pi} invariant and kappa, and (iii) derive the temperature and density, respectively, from the slope and intercept of the linear relationship between kappa and logarithm of {\Pi}. We find the following thermodynamic characteristics: (1) Temperature sky-maps and histograms shifted to their lowest values in 2012 and their highest in 2015; (2) Temperature negatively correlated with density, reflecting the subisothermal polytropic behavior; (3) Temperature positively correlated with kappa, revealing characteristics of the mechanism responsible for generating kappa distributions; (4) Processes in IHS are sub-isothermal tending toward isobaric, consistent with previously published results; (5) Linear relationship between kappa and polytropic indices, revealing characteristics of the particle potential energy; and (6) Entropy positively correlated with polytropic index, aligned with the underlying theory that entropy increases towards the isothermal state where the kappa distribution reduces to the Maxwell Boltzmann description.