Implementation of mixed-dimensional models for flow in fractured porous media
This work provides a reusable simulation framework for mixed-dimensional flow problems in fractured porous media, relevant to geoscience and engineering applications.
The paper presents a simulation framework for flow in fractured porous media using mixed-dimensional models, representing the geometry as a graph for discretization and coupling dimensions via boundary conditions. It demonstrates results for a 3D fracture problem with finite volume and virtual finite element methods.
Models that involve coupled dynamics in a mixed-dimensional geometry are of increasing interest in several applications. Here, we describe the development of a simulation model for flow in fractured porous media, where the fractures and their intersections form a hierarchy of interacting subdomains. We discuss the implementation of a simulation framework, with an emphasis on reuse of existing discretization tools for mono-dimensional problems. The key ingredients are the representation of the mixed-dimensional geometry as a graph, which allows for convenient discretization and data storage, and a non-intrusive coupling of dimensions via boundary conditions and source terms. This approach is applicable for a wide class of mixed-dimensional problems. We show simulation results for a flow problem in a three-dimensional fracture geometry, applying both finite volume and virtual finite element discretizations.