Prolong Impact of Temperature on CO2Dissolution in Finite Heterogeneous Saline Aquifers
Salaudeen I. Khoramian R. Riazi M. Pourafshary P. Cortés F.B.
29 January 2026American Chemical Society
Energy and Fuels
2026#40Issue 42075 - 2090 pp.
Increasing atmospheric CO2 levels call for secure, large-scale storage methods, and deep brine reservoirs represent the most widely available and scalable option. However, accurately predicting long-term CO2 dissolution in these systems remains challenging and difficult because of the complex chemistry of temperature, heterogeneity, capillary forces, and geochemical reactions. This research employs advanced numerical simulations to evaluate these effects on the dissolution of CO2 in heterogeneous, finite saline aquifers. A key novelty is the integration of experimentally derived diffusion coefficients, extended to higher temperatures via Arrhenius-based predictions, into the CMG simulator, thereby strengthening the linkage between laboratory data and reservoir-scale modeling. The simulations examine CO2 dissolution across a wide temperature range (35–100 °C) while systematically evaluating the roles of capillary forces, aquifer heterogeneity, salinity, brine density evolution, and mineral–fluid reactions on plume morphology and trapping. To reduce computational complexity, three representative temperature levels (low, medium, and high ranges) were selected for the sensitivity analysis. Results reveal that at 35 °C, capillary forces enhance CO2 dissolution efficiency by roughly 7%, driven by lower molecular kinetic energy and stronger interfacial interactions within confined pore spaces. Nonetheless, this effect diminishes at 100 °C due to the increased molecular energy and lower interfacial tension. Without geochemical interactions, dissolution efficiency increases by roughly 20% with temperature, from 45% at 35 °C to 70% at 100 °C. With geochemistry considered, redistribution of dissolved CO2 into ionic and mineral-associated species reduces the apparent efficiency to around 36 and 47% at 35 and 100 °C, respectively. Finally, the findings demonstrate the necessity of accurate diffusion parametrization and the coupled consideration of temperature, capillary forces, geochemistry, and heterogeneity for predicting long-term CO2 dissolution and trapping in deep saline aquifers.
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School of Mining and Geosciences, Nazarbayev University, Astana, 01000, Kazakhstan
Grupo de investigación en Fenómenos de Superficie-Michael Polanyi, Facultad de Minas, Universidad Nacional de Colombia - Sede Medellín, Medellín, 050034, Colombia
School of Mining and Geosciences
Grupo de investigación en Fenómenos de Superficie-Michael Polanyi
10 лет помогаем публиковать статьи Международный издатель
Книга Публикация научной статьи Волощук 2026 Book Publication of a scientific article 2026