A Fat boundary-type method for localized nonhomogeneous material problems

TL;DR

This paper introduces a Fat boundary-type method to efficiently handle localized nonhomogeneous material problems in numerical simulations, especially when fine meshes are needed in small, complex regions that change over time.

Contribution

The paper proposes and analyzes a Fat boundary-type method as an alternative to nonuniform meshing for localized material problems, with validation through numerical tests.

Findings

The method effectively manages localized nonhomogeneous regions.

Mathematical analysis supports the method's validity.

Numerical tests demonstrate practical applicability.

Abstract

Problems with localized nonhomogeneous material properties arise frequently in many applications and are a well-known source of difficulty in numerical simulations. In certain applications (including additive manufacturing), the physics of the problem may be considerably more complicated in relatively small portions of the domain, requiring a significantly finer local mesh compared to elsewhere in the domain. This can make the use of a uniform mesh numerically unfeasible. While nonuniform meshes can be employed, they may be challenging to generate (particularly for regions with complex boundaries) and more difficult to precondition. The problem becomes even more prohibitive when the region requiring a finer-level mesh changes in time, requiring the introduction of refinement and derefinement techniques. To address the aforementioned challenges, we employ a technique related to the Fat boundary method as a possible alternative. We analyze the proposed methodology, from a mathematical point of view and validate our findings on two-dimensional numerical tests.