The convective Allen-Cahn equation has been widely used to simulate multi-phase flows in many phase-field models. As a generalized form of the classic Allen-Cahn equation, the convective Allen-Cahn equation still preserves the maximum bound principle (MBP) in the sense that the time-dependent solution of the equation with appropriate initial and boundary conditions preserves for all time a uniform pointwise bound in absolute value. In this paper, we develop efficient first- and second-order exponential time differencing (ETD) schemes combined with the linear stabilizing technique to preserve the MBP unconditionally in the discrete setting. The space discretization is done using the upwind difference scheme for the convective term and the central difference scheme for the diffusion term, and both the mobility and nonlinear terms are approximated through the linear convex interpolation. The unconditional preservation of the MBP of the proposed schemes is proven, and their convergence analysis is presented. Various numerical experiments in two and three dimensions are also carried out to verify the theoretical results.
翻译:Allen-Cahn等式作为典型的Allen-Cahn等式的一种普遍形式,对等Allen-Cahn等式仍然保留了最大约束原则(MBP),因为具有适当初始条件和边界条件的对等法的基于时间的解决方案在绝对值上始终保持一个统一的点约束。在本文件中,我们制定了有效的一、二级指数时间差异办法,结合线性稳定技术,无条件在离散环境中保持MBP。空间离散是利用对流术语的上风差异办法和扩散术语的中心差异办法进行的,流动和非线性术语都是通过线性对线性矩形的相互调而相近的。对拟议方案MBP的无条件维护得到了证明,并提出了其趋同分析。还进行了两个和三个层面的各种数字实验,以核实理论结果。