SFEM for the unsteady Navier-Stokes Equations on a stationary surface

Abstract

In this paper we consider a fully discrete numerical method for the unsteady Navier-Stokes equations on a smooth closed stationary surface in R3. We use the surface finite element method (SFEM) with a generalized Taylor-Hood finite element pair Pku-- Pkpr-- Pkλ, where we enforce the tangential condition of the velocity field weakly, by introducing an extra Lagrange multiplier λ. Depending on the richness of the finite element space involving this extra Lagrange multiplier we present a fully discrete stability and error analysis. For the velocity, we establish optimal L2(ah)-norm bounds (ah - an energy norm) when kλ=ku and suboptimal with respect to the geometric approximation error when kλ = ku-1 (optimal when super-parametric finite elements are used). For the pressure, optimal L2(L2)-norm error bounds are established when kλ=ku. Assuming further regularity assumptions for our continuous problem, we are also able to show optimal convergence (using super-parametric finite elements again) when kλ=ku-1. Numerical simulations that confirm the established theory are provided, along with a comparative analysis against a penalty approach.