Partially dissipative one-dimensional hyperbolic systems in the critical regularity setting, and applications

Abstract

Here we develop a method for investigating global strong solutions of partially dissipative hyperbolic systems in the critical regularity setting. Compared to the recent works by Kawashima and Xu, we use hybrid Besov spaces with different regularity exponents in low and high frequencies. This allows us to consider more general data and to track the exact dependency on the dissipation parameter for the solution. Our approach enables us to go beyond the $L^2$ framework in the treatment of the low frequencies of the solution, which is totally new, to the best of our knowledge.

The focus is on the one-dimensional setting (the multidimensional case will be considered in a forth-coming paper) and, for expository purposes, the first part of the paper is devoted to a toy model that may be seen as a simplification of the compressible Euler system with damping. More elaborate systems (including the compressible Euler system with general increasing pressure law) are considered at the end of the paper.