An Application of Nash-Moser Theorem to Smooth Solutions of One-Dimensional Compressible Euler Equation with Gravity

TL;DR

This paper applies Nash-Moser theory to justify the existence of smooth solutions for a one-dimensional compressible Euler equation with gravity, overcoming regularity loss issues near vacuum boundaries.

Contribution

It introduces a novel application of Nash-Moser iteration to establish long-time solutions for Euler equations with gravity, transforming the problem into a higher-dimensional nonlinear wave equation.

Findings

Successfully justified the solution expansion using Nash-Moser theory.

Demonstrated the transformation to a higher-dimensional wave equation.

Addressed regularity loss issues near vacuum boundaries.

Abstract

We study one-dimensional motions of polytropic gas governed by the compressible Euler equations. The problem on the half space under a constant gravity gives an equilibrium which has free boundary touching the vacuum and the linearized approximation at this equilibrium gives time periodic solutions. But it is not easy to justify the existence of long-time true solutions for which this time periodic solution is the first approximation. The situation is in contrast to the problem of free motions without gravity. The reason is that the usual iteration method for quasilinear hyperbolic problem cannot be used because of the loss of regularities which causes from the touch with the vacuum. Interestingly, the equation can be transformed to a nonlinear wave equation on a higher dimensional space, for which the space dimension, being larger than 4, is related to the adiabatic exponent of the original one-dimensional problem. We try to find a family of solutions expanded by a small parameter. Applying the Nash-Moser theory, we justify this expansion.The application of the Nash-Moser theory is necessary for the sake of conquest of the trouble with loss of regularities, and the justification of the applicability requires a very delicate analysis of the problem.