Samuel Burbulla, doctoral researcher at the Institute of Applied Analysis and Numerical Simulation (IANS), and member within the framework of SFB 1313 and the Integrated Research Training Group IRTG-IMPM, will defend his dissertation:
Title: "Mixed-Dimensional Modeling of Flow in Porous Media"
Date: 20 December 2022
Time: 2 pm CET
Venue: Institute of Applied Analysis and Numerical Simulation, room 8.122, Pfaffenwaldring 57, 70569 Stuttgart
Abstract
Modeling flow in dynamically fracturing porous media is of high interest for a wide range of natural and technical applications, for instance, geothermal energy production or carbon capture and storage. In this work, we present new mixed-dimensional models for flow in porous media including fractures with time- and space-dependent geometries. The models are implemented using our new grid implementation Dune-MMesh which is tailored for the discretization of mixed-dimensional partial differential equations with fully conforming interface of codimension one.
First, we propose a mixed-dimensional model for capillarity-free two-phase flow in dynamically fracturing porous media. The model is discretized by a fully conforming finite-volume moving-mesh algorithm that explicitly tracks the fracture geometry. Further, generalizing an earlier model for single-phase flow in fractured porous media, we derive a dimensionally reduced model including spatially varying apertures. In several numerical examples, using a mixed-dimensional discontinuous Galerkin discretization, the model demonstrates significant improvements for curvilinear fracture geometries.
Finally, we propose a mixed-dimensional phase-field model for fracture propagation in poro-elastic media combining discrete fracture and phase-field modeling approaches. The corresponding discontinuous Galerkin discretization tracks the fracture geometry by adding facets to the fracture triangulation according to the phase-field indicator and is validated with results known from literature.