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Nonlocal-to-Local Convergence of Cahn–Hilliard Equations: Neumann Boundary Conditions and Viscosity Terms

Elisa Davoli, Luca Scarpa, Lara Trussardi

2020Archive for Rational Mechanics and Analysis40 citationsDOIOpen Access PDF

Abstract

We consider a class of nonlocal viscous Cahn-Hilliard equations with Neumann boundary conditions for the chemical potential. The double-well potential is allowed to be singular (e.g. of logarithmic type), while the singularity of the convolution kernel does not fall in any available existence theory under Neumann boundary conditions. We prove well-posedness for the nonlocal equation in a suitable variational sense. Secondly, we show that the solutions to the nonlocal equation converge to the corresponding solutions to the local equation, as the convolution kernels approximate a Dirac delta. The asymptotic behaviour is analyzed by means of monotone analysis and Gamma convergence results, both when the limiting local Cahn-Hilliard equation is of viscous type and of pure type.

Topics & Concepts

MathematicsSingularityCahn–Hilliard equationNeumann boundary conditionMathematical analysisBoundary (topology)Boundary value problemConvolution (computer science)Partial differential equationArtificial neural networkMachine learningComputer scienceSolidification and crystal growth phenomenaNonlinear Partial Differential EquationsAdvanced Mathematical Modeling in Engineering
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