Extended analysis of benchmarks for gas phase appearance in low-permeable rocks

Grunwald, Norbert; Nagel, Thomas; Pitz, Michael; Kolditz, Olaf

doi:10.1007/s40948-023-00703-3

Cited by 3 publications

References 21 publications

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On Multi-Component Gas Migration in Single-Phase Systems

Pitz,

Jacops,

Grunwald

et al. 2024

Rock Mech Rock Eng

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The present work deals with diffusion of gases in fully saturated porous media. We test and validate the gas transport mechanism of dissolution and diffusion, implemented in the TH2M process class in the open-source finite-element software OpenGeoSys. We discuss the importance of gas diffusion for the integrity of the multi-barrier system. Furthermore, we present a multi-component mass balance equation implementation in Python, which serves as a reference for the two-component TH2M implementation and allows for a discussion of multi-component gas diffusion in liquids. We verify and validate the numerical implementations as follows: First, we come up with a set of numerical benchmarks in which solutions obtained by the two-component TH2M and multi-component implementations are compared. Thus, we show under which conditions predictions made by the TH2M model can be used for multi-component gas systems. Finally, the work is validated using a through diffusion experiment performed at Belgium’s Nuclear Research Centre SCK CEN and a sensitivity analysis is conducted based on the featured experiment. The results of this work illustrate that predictions by both the two- and four-component models match the laboratory findings very well. Therefore, we conclude that also the two-component implementation can reflect the multi-component processes well under the given constraints such as full saturation.

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On Multi-Component Gas Migration in Single-Phase Systems

Pitz,

Jacops,

Grunwald

et al. 2024

Rock Mech Rock Eng

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OpenWorkFlow—Development of an open-source synthesis-platform for safety investigations in the site selection process

Lehmann,

Bilke,

Buchwald

et al. 2024

Grundwasser - Zeitschrift der Fachsektion Hydrogeologie

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The identification of appropriate locations for secure nuclear waste disposal, a crucial aspect of Germany’s nuclear phase-out strategy (StandAG 2017), remains a significant scientific, technical, and political challenge worldwide. The selection and safety assessment of sites demand extensive applications of numerical methods. The OpenWorkFlow project, initiated by Bundesgesellschaft für Endlagerung (BGE), develops a new, open synthesis platform to virtualise repository systems. The simulation platform will evaluate far-field and near-field processes, supporting the site selection process first and the geotechnical design of repository systems later on. The project’s development philosophy adheres to the principles of continuity and innovation. Through continuous scientific development, the OpenWorkFlow platform will remain at the forefront of science and technology. Furthermore, as a digital platform, OpenWorkFlow employs up-to-date IT methods and constantly evolving software concepts. As its name suggests, OpenWorkFlow (OWF) is an open platform, developed on the basis of FAIR principles as an open-source project, inviting community participation.This paper primarily focuses on the technical aspects of OWF, with only a brief discussion of conceptual principles and modelling methods. In the second part of the manuscript, demonstration examples from different scales are presented to illustrate the current technical status of OWF and to emphasize the requirement for further development.

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