De Paoli, M., Zonta, F., Enzenberger, L. R., Coliban, E., & Pirozzoli, S. (2025). Simulation and Modeling of Convective Mixing of Carbon Dioxide in Geological Formations. Geophysical Research Letters, 52(7), Article e2025GL114804. https://doi.org/10.1029/2025GL114804
CO2 sequestration; convection; mixing; modeling; porous media; simulations
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Abstract:
We perform large-scale numerical simulations of convection in 3D porous media at Rayleigh-Darcy numbers up to o Ra = 8 × 10⁴.. To investigate the convective mixing of carbon dioxide (CO₂) in geological formations, we consider a semi-infinite domain, where the CO₂ concentration is constant at the top and no flux is prescribed at bottom. Convection begins with a diffusion-dominated phase, transitions to convection-driven solute finger growth, and ends with a shutdown stage as fingers reach the bottom boundary and the concentration in the system increases. For Ra ≥ 5 × 10³, we observe a constant-flux regime with dissolution flux stabilizing at 0.019, approximately 13% higher than in 2D estimates. Finally, we provide a simple and yet accurate physical model describing the mass of solute entering the system throughout the whole mixing process. These findings extend solutal convection insights to 3D and high-Ra, improving the reliability of tools predicting the long-term CO₂ dynamics in the subsurface.
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Project (external):
European Union's Horizon Europe research and innovation programme under the Marie Sklodowska-Curie grant EuroHPC JointUndertaking TU Wien Bibliothek
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Project ID:
MEDIA No. 101062123 GEOCOSE number EHPC-REG-2022R03-207 Open Access Funding Programme
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Research Areas:
Computational Fluid Dynamics: 50% Modeling and Simulation: 50%
