A Cahn--Hilliard--Willmore phase field model for non-oriented interfaces
Abstract
We investigate a new phase field model for representing non-oriented interfaces, approximating their area and simulating their area-minimizing flow. Our contribution is related to the approach proposed in arXiv:2105.09627 that involves ad hoc neural networks. We show here that, instead of neural networks, similar results can be obtained using a more standard variational approach that combines a Cahn-Hilliard-type functional involving an appropriate non-smooth potential and a Willmore-type stabilization energy. We give a -convergence analysis of this phase field model in dimension 1 and, for radially symmetric functions, in arbitrary dimension. We also propose a simple numerical scheme to approximate its L2-gradient flow. We illustrate numerically that the new flow approximates fairly well the mean curvature flow of codimension 1 or 2 interfaces in dimensions 2 and 3.
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