The present work focuses on the development of GReS, a novel open-source modular platform designed for testing and prototyping numerical algorithms for fully coupled multi-physics multi-domain poromechanical simulations. The idea is to partition the overall computational domain into possibly non-conforming sub-domains where different physics and discretizations can be used. An innovative variant of the mortar method is implemented to transfer the information among non-conforming sub-domains with independent grids. The code is tested in a benchmark to show its current potential.

Advances in Multi-physics and Multi-domain Simulations of Coupled Poromechanics

Ferronato, Massimiliano
;
Franceschini, Andrea;Moretto, Daniele
2026

Abstract

The present work focuses on the development of GReS, a novel open-source modular platform designed for testing and prototyping numerical algorithms for fully coupled multi-physics multi-domain poromechanical simulations. The idea is to partition the overall computational domain into possibly non-conforming sub-domains where different physics and discretizations can be used. An innovative variant of the mortar method is implemented to transfer the information among non-conforming sub-domains with independent grids. The code is tested in a benchmark to show its current potential.
2026
Large-Scale Scientific Computations
9783032222206
9783032222213
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11577/3603799
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