A Second Order Energy Stable Scheme for the Cahn-Hilliard-Hele-Shaw Equations

Abstract

We present a second-order-in-time finite difference scheme for the Cahn-Hilliard-Hele-Shaw equations. This numerical method is uniquely solvable and unconditionally energy stable. At each time step, this scheme leads to a system of nonlinear equations that can be efficiently solved by a nonlinear multigrid solver. Owing to the energy stability, we derive an 2 (0,T; Hh3) stability of the numerical scheme. To overcome the difficulty associated with the convection term ∇ · (ϕu), we perform an ∞ (0,T; Hh1) error estimate instead of the classical ∞ (0,T; 2) one to obtain the optimal rate convergence analysis. In addition, various numerical simulations are carried out, which demonstrate the accuracy and efficiency of the proposed numerical scheme.