Higher-order streamfunction-vorticity formulation of 2D steady-state Navier-Stokes equations

In this paper the high-order formulations described by Liao (In?. j . numer: methodspuids, 15,595412 (1992)) are proved to be stable for viscous flow under high Reynolds number. As an example, results for shear-dnven flow in a square cavity at Reynolds numbers up to 10,000 are given.

## Abstract A fourth‐order compact finite difference scheme on the nine‐point 2D stencil is formulated for solving the steady‐state Navier–Stokes/Boussinesq equations for two‐dimensional, incompressible fluid flow and heat transfer using the stream function–vorticity formulation. The main feature o

We use the bivariate spline finite elements to numerically solve the steady state Navier-Stokes equations. The bivariate spline finite element space we use in this article is the space of splines of smoothness r and degree 3r over triangulated quadrangulations. The stream function formulation for th

By a result of Foias and Saut, the quotient of the enstrophy and the energy of a solution of the Navier Stokes equations with potential forces converges to the square root of an eigenvalue 4 k of the Stokes operator. We study the Hausdorff length (H 1 ) of the level sets of the vorticity and the str