High order semi-implicit weighted compact nonlinear scheme for the full compressible Euler system at all Mach numbers

Abstract

A high order semi-implicit weighted compact nonlinear scheme (WCNS) is presented to solve the full compressible Euler equations at all Mach numbers. To avoid the stringent acoustic CFL restriction for an explicit time discretization method, the pressure splitting methodology is introduced to split the Euler equations into nonstiff and stiff terms. The nonstiff and stiff terms are treated explicitly and implicitly, respectively, based on the high order IMEX Runge-Kutta time discretization method that is asymptotic preserving and asymptotically accurate in the zero Mach number limit. A fifth-order WCNS and fourth-order centered finite difference schemes with zero numerical viscosity are used for the spatial discretization. Numerical tests in one and two space dimensions are displayed to demonstrate the performance of the high order semi-implicit WCNS in compressible and incompressible regimes. Comparisons with the third-order explicit weighted essentially non-oscillatory (WENO) scheme are also made in order to better assess the proposed scheme.