Constructing characteristic initial data for three dimensional compressible Euler equations

Abstract

This paper resolves the characteristic initial data problem for the three-dimensional compressible Euler equations - an open problem analogous to Christodoulou's characteristic initial value formulation for the vacuum Einstein field equations in general relativity. Within the framework of acoustical geometry, we prove that for any "initial cone" C0⊂ D=[0,T]×R3 with initial data (,v,s) given at S0,0=C0 0, arbitrary smooth entropy function and angular velocity determine smooth initial data (,v,s) on C0 that render C0 characteristic. Differing from the intersecting-hypersurface case by Speck-Yu [19] and the symmetric reduction case by Lisibach [11], our vector field method recursively determines all (including 0-th) order derivatives of the solution along C0 via transport equations and wave equations. This work provides a complete characteristic data construction for admissible hypersurfaces in the 3D compressible Euler system, introducing useful tools and providing novel aspects for studies of the long-time dynamics of the compressible Euler flow.