Large scale lattice Boltzmann simulation for the coupling of free and porous media flow

Fattahi E, Waluga C, Wohlmuth BI, Rüde U (2016)


Publication Language: English

Publication Type: Conference contribution, Original article

Publication year: 2016

Publisher: Springer

Conference Proceedings Title: High Performance Computing in Science and Engineering

Event location: Ostrava CZ

ISBN: 978-3-319-40361-8

DOI: 10.1007/978-3-319-40361-8

Abstract

In this work, we investigate the interaction of free and porous media flow by large scale lattice Boltzmann simulations. We study the transport phenomena at the porous interface on multiple scales, i.e., we consider both, computationally generated pore-scale geometries and homogenized models at a macroscopic scale. The pore-scale results are compared to those obtained by using different transmission models. Two-domain approaches with sharp interface conditions, e.g., of Beavers--Joseph--Saffman type, as well as a single-domain approach with a porosity depending viscosity are taken into account. For the pore-scale simulations, we use a highly scalable communication-reducing scheme with a robust second order boundary handling. We comment on computational aspects of the pore-scale simulation and on how to generate pore-scale geometries. The two-domain approaches depend sensitively on the choice of the exact position of the interface, whereas a well-designed single-domain approach can significantly better recover the averaged pore-scale results.

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How to cite

APA:

Fattahi, E., Waluga, C., Wohlmuth, B.I., & Rüde, U. (2016). Large scale lattice Boltzmann simulation for the coupling of free and porous media flow. In High Performance Computing in Science and Engineering. Ostrava, CZ: Springer.

MLA:

Fattahi, Ehsan, et al. "Large scale lattice Boltzmann simulation for the coupling of free and porous media flow." Proceedings of the High Performance Computing in Science and Engineering, Ostrava Springer, 2016.

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