Long time existence of smooth solutions to 2D compressible Euler equations of Chaplygin gases with non-zero vorticity

Abstract

For the 2D compressible isentropic Euler equations of polytropic gases with an initial perturbation of size of a rest state, it has been known that if the initial data are rotationnally invariant or irrotational, then the lifespan T of the classical solutions is of order O(12); if the initial vorticity is of size 1+ (0 1), then T is of O(11+). In the present paper, for the 2D compressible isentropic Euler equations of Chaplygin gases, if the initial data are a perturbation of size , and the initial vorticity is of any size with 0< , we will establish the lifespan T=O(1). For examples, if =e-12 or =e-e12 are chosen, then T=O(e12) or T=O(ee12) although the perturbations of the initial density and the divergence of the initial velocity are only of order O(). Our main ingredients are: finding the null condition structures in 2D compressible Euler equations of Chaplygin gases and looking for the good unknown; establishing a new class of weighted space-time L∞-L∞ estimates for the solution itself and its gradients of 2D linear wave equations; introducing some suitably weighted energies and taking the Lp (1<p<∞) estimates on the vorticity.