Well-posedness and time-asymptotic of Boltzmann equations for monatomic and polyatomic mixtures
Abstract
This paper considers a system of Boltzmann equations modelling the mixture of monatomic and polyatomic gases in an L2-L∞ perturbation theory around global modified Maxwellians accounting for the internal energy of the mixture in the whole space and the torus. We investigate the pointwise decay in velocity and internal energy of the linearized Boltzmann operators in the four types of collisions. A novel approach is developed to deal with the additional internal energy variable I∈ R+ and the loss of symmetry due to dissimilar masses of the mixture components. Subsequently, we carry out a classical L2-L∞ method to establish the well-posedness theory of the system. The optimal polynomial time decay rate on the whole space is obtained accordingly based on the spatial Fourier's study of the linearized system. The analysis shows the structure of a perturbed Euler-type model for the solution's macroscopic quantities: density, bulk velocity, and temperature, near the steady state, which gives a potential application to investigate fluid limit problems. In addition, this work proves exponential time decay in the torus and fills the gap of classical multi-species Boltzmann in the whole space.
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