Generalized SAV-exponential integrator schemes for Allen-Cahn type gradient flows

Abstract: The energy dissipation law and the maximum bound principle (MBP) are two important physical features of the well-known Allen-Cahn equation. While some commonly-used first-order time stepping schemes have turned out to preserve unconditionally both energy dissipation law and MBP for the equation, restrictions on the time step size are still needed for existing secondorder or even higher-order schemes in order to have such simultaneous preservation. In this paper, we develop and analyze novel first-and second-or… Show more

“…In [27], Shen and Zhang derived the spectral element method for a generalized Allen-Cahn equation coupled with passive convection for a given incompressible velocity field, which can preserve the maximum bound principle. In [18], Ju et al developed first-and second-order linear finite difference schemes for a class of Allen-Cahn type gradient flow by combining the generalized SAV approach and the exponential time integrator with a stabilization term. Some other numerical analyses can see [19,26,28,29] and the references therein.…”

A generalized scalar auxiliary variable method for the time-dependent Ginzburg-Landau equations

“…In [27], Shen and Zhang derived the spectral element method for a generalized Allen-Cahn equation coupled with passive convection for a given incompressible velocity field, which can preserve the maximum bound principle. In [18], Ju et al developed first-and second-order linear finite difference schemes for a class of Allen-Cahn type gradient flow by combining the generalized SAV approach and the exponential time integrator with a stabilization term. Some other numerical analyses can see [19,26,28,29] and the references therein.…”

A generalized scalar auxiliary variable method for the time-dependent Ginzburg-Landau equations