Optimal convergence analysis of fully discrete SAVs-FEM for the Cahn-Hilliard-Navier-Stokes equations
Abstract
We construct a fully discrete numerical scheme that is linear, decoupled, and unconditionally energy stable, and analyze its optimal error estimates for the Cahn-Hilliard-Navier-Stokes equations. For time discretization, we employ the two scalar auxiliary variables (SAVs) and the pressure-correction projection method. For spatial discretization, we choose the Pr × Pr × Pr+1 × Pr finite element spaces, where r is the degree of the local polynomials, and derive the optimal L2 error estimates for the phase-field variable, chemical potential, and pressure in the case of r ≥ 1, and for the velocity when r ≥ 2, without relying on the quasi-projection operator technique proposed in [Cai et al. SIAM J Numer Anal, 2023]. Numerical experiments validate the theoretical results, confirming the unconditional energy stability and optimal convergence rates of the proposed scheme. Additionally, we numerically demonstrate the optimal L2 convergence rate for the velocity when r=1.
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