The content presents a numerical method for the multi-phase Mullins-Sekerka problem, which describes the evolution of a network of curves that partition a domain into multiple phases. The key highlights and insights are:
The authors derive a weak formulation of the problem, which encodes the motion law, Gibbs-Thomson law, and the balance of forces at triple junctions.
They introduce a parametric finite element method that approximates the moving interfaces independently of the discretization used for the bulk equations. This scheme is shown to be unconditionally stable and to satisfy an exact volume conservation property.
The discretization features an inherent tangential velocity for the vertices on the discrete curves, leading to asymptotically equidistributed vertices without the need for remeshing.
The authors provide a detailed discussion on the solution of the linear systems arising from the discrete problem, including techniques to avoid complications due to the nonstandard finite element spaces.
Several numerical examples, including a convergence experiment for the three-phase Mullins-Sekerka flow, demonstrate the capabilities of the introduced method.
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