English

Energy stable arbitrary order ETD-MS method for gradient flows with Lipschitz nonlinearity

Numerical Analysis 2021-02-23 v1 Numerical Analysis

Abstract

We present a methodology to construct efficient high-order in time accurate numerical schemes for a class of gradient flows with appropriate Lipschitz continuous nonlinearity. There are several ingredients to the strategy: the exponential time differencing (ETD), the multi-step (MS) methods, the idea of stabilization, and the technique of interpolation. They are synthesized to develop a generic kthk^{th} order in time efficient linear numerical scheme with the help of an artificial regularization term of the form AτktLp(k)uA\tau^k\frac{\partial}{\partial t}\mathcal{L}^{p(k)}u where L\mathcal{L} is the positive definite linear part of the flow, τ\tau is the uniform time step-size. The exponent p(k)p(k) is determined explicitly by the strength of the Lipschitz nonlinear term in relation to L\mathcal{L} together with the desired temporal order of accuracy kk. To validate our theoretical analysis, the thin film epitaxial growth without slope selection model is examined with a fourth-order ETD-MS discretization in time and Fourier pseudo-spectral in space discretization. Our numerical results on convergence and energy stability are in accordance with our theoretical results.

Keywords

Cite

@article{arxiv.2102.10988,
  title  = {Energy stable arbitrary order ETD-MS method for gradient flows with Lipschitz nonlinearity},
  author = {Wenbin Chen and Shufen Wang and Xiaoming Wang},
  journal= {arXiv preprint arXiv:2102.10988},
  year   = {2021}
}
R2 v1 2026-06-23T23:23:56.029Z