On the Cauchy problem for Boltzmann equation modeling a polyatomic gas

In the present article, we consider the Boltzmann equation that models a polyatomic gas by introducing one additional continuous variable, referred to as microscopic internal energy. We establish existence and uniqueness theory in the space homogeneous setting for the full non-linear case, under an extended Grad-type assumption on transition probability rates, which comprises hard potentials for both the relative speed and internal energy with the rate in the interval 0,2, multiplied by an integrable angular part and integrable partition functions. The Cauchy problem is resolved by means of an abstract ordinary differential equation (ODE) theory in Banach spaces for the initial data with finite and strictly positive gas mass and energy, finite momentum, and additionally finite K-* polynomial moment, with K-* depending on the rate of the transition probability and the structure of a polyatomic molecule or its internal degrees of freedom. Moreover, we prove that polynomially and exponentially weighted Banach space norms associated with the solution are both generated and propagated uniformly in time.

Automated summary

In this article, we study the Boltzmann equation for modeling polyatomic gases with the introduction of a microscopic internal energy variable. We establish the existence and uniqueness theory for the full non-linear case under an extended Grad-type assumption on transition probability rates. The Cauchy problem is solved using abstract ordinary differential equation (ODE) theory in Banach spaces, with various constraints on the initial data.