Domain Decomposition for Compressible Navier-Stokes Equations with Different Discretizations and Formulations

## Communicated by Y. Shibata We investigate the steady compressible Navier-Stokes equations near the equilibrium state v"0, " (v the velocity, the density) corresponding to a large potential force. We introduce a method of decomposition for such equations: the velocity field v is split into a non

For the solution of practical flow problems in arbitrarily shaped domains, simple Schwarz domain decomposition methods with minimal overlap are quite efficient, provided Krylov subspace methods, e.g. the GMRES method, are used to accelerate convergence. With an accurate subdomain solution, the amoun

This paper describes a domain decomposition method for the incompressible Navier -Stokes equations in general co-ordinates. Domain decomposition techniques are needed for solving flow problems in complicated geometries while retaining structured grids on each of the subdomains. This is the so-called

We show that for the P N -P N -2 spectral element method, in which velocity and pressure are approximated by polynomials of order N and N -2, respectively, numerical instabilities can occur in the spatially discretized Navier-Stokes equations. Both a staggered and nonstaggered arrangement of the N -

## Abstract In this paper, we prove global well‐posedness for compressible Navier‐Stokes equations in the critical functional framework with the initial data close to a stable equilibrium. This result allows us to construct global solutions for the highly oscillating initial velocity. The proof rel