Reduced kinetic model of polyatomic gases

TL;DR

This paper introduces a simplified kinetic model for polyatomic gases that captures rotational energy dynamics, respects thermodynamic principles, and accurately recovers hydrodynamic behavior with tunable transport properties.

Contribution

It extends the ES-BGK model to include rotational energy with an advection-diffusion-relaxation equation, maintaining thermodynamic consistency and enabling tunable transport coefficients.

Findings

Model respects the H theorem.

Recovers compressible hydrodynamics.

Allows for three independent transport coefficients.

Abstract

Kinetic models of polyatomic gas typically account for the internal degrees of freedom at the level of the two-particle distribution function. However, close to the hydrodynamic limit, the internal (rotational) degrees of freedom tend to be well represented just by rotational kinetic energy density. We account for the rotational energy by augmenting the Ellipsoidal-statistical BGK (ES-BGK) model, an extension of the Bhatnagar-Gross- Krook (BGK) model, at the level of the single-particle distribution function with an advection-diffusion-relaxation equation for the rotational energy. This reduced model respects the H theorem and recovers the compressible hydrodynamics for polyatomic gases as its macroscopic limit. As required for a polyatomic gas model, this extension of the ES-BGK model has not only correct specific heat ratio but also allows for three independent tunable transport coefficients: thermal conductivity, shear viscosity, and bulk viscosity. We illustrate the effectiveness of the model via a lattice Boltzmann method implementation.