Numerical investigation on the influence of CO2-induced mineral dissolution on hydrogeological and mechanical properties of sandstone using coupled lattice Boltzmann and finite element model

•A novel model integrating lattice Boltzmann and finite element methods is proposed.•Varied dissolution modes lead to distinct permeability and mechanical properties.•These properties can be better described via fractal parameters instead of porosity. The impact of CO2-induced mineral reactions, spe...

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Veröffentlicht in:Journal of hydrology (Amsterdam) 2024-08, Vol.639, p.131616, Article 131616
Hauptverfasser: Yang, Bo, Xu, Tianfu, Du, Yiling, Jiang, Zhenjiao, Tian, Hailong, Yuan, Yilong, Zhu, Huixing
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Sprache:eng
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Zusammenfassung:•A novel model integrating lattice Boltzmann and finite element methods is proposed.•Varied dissolution modes lead to distinct permeability and mechanical properties.•These properties can be better described via fractal parameters instead of porosity. The impact of CO2-induced mineral reactions, specifically the CO2-water-rock interactions, has been widely recognized for its potential to compromise the hydrogeological and mechanical properties of porous media, thereby deteriorating their integrity and mechanical characteristics. This raises concerns regarding the safety of numerous projects such as CO2 geological storage. However, the mechanism underlying the influence of CO2-induced mineral reactions on these parameters is still not fully understood, thereby introducing uncertainty into the reliability of predicted outcomes. Direct pore-scale simulation plays a crucial role in deepening the understanding of CO2 -water-rock interaction and its associated impacts. The present study proposes a novel simulation model that integrates the lattice Boltzmann and finite element methods to simulate the dissolution of calcite in a 3D sandstone sample invaded by saturated CO2 solution, aiming to investigate the resulting evolution of hydrogeological parameters (i.e., porosity and permeability) and mechanical properties (i.e., bulk and shear moduli). The injection rates of reactive fluid (i.e., CO2 solution) were varied in the model to simulate different operational conditions of CO2 geological storage project. The simulation results demonstrate that the decrease in injection velocity inhibits the dissolution of calcite in the middle and downstream regions, concentrating it near the inlet. These distinct modes of calcite dissolution result in differentiated permeability and mechanical properties within rocks possessing identical porosity levels. In general, the increase in fluid injection velocity leads to a more pronounced enhancement in permeability and a greater attenuation in bulk and shear moduli under the same porosity. Thus, it is confirmed that the utilization of porosity is inadequate in accurately characterizing the evolution of rock permeability and mechanical properties resulting from mineral reactions. We ascertain that the application of fractal parameters, i.e., succolarity and fractal dimension, can more precisely depict the progression of permeability and bulk/shear modulus, respectively.
ISSN:0022-1694
DOI:10.1016/j.jhydrol.2024.131616