Litcius/Paper detail

Reactivity and Dissolution Characteristics of Naturally Altered Basalt in CO<sub>2</sub>-Rich Brine: Implications for CO<sub>2</sub> Mineralization

Jiajie Wang, Masahiko Yagi, Tetsuya Tamagawa, Hitomi Hirano, Noriaki Watanabe

2024ACS Omega25 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Hydrothermally altered basaltic rocks are widely distributed and more accessible than fresh basaltic rocks, making them attractive feedstocks for permanent CO 2 storage through mineralization. This study investigates the reactivity and dissolution behaviors of altered basalt during the reaction with CO 2 -rich fluids and compares it with unaltered basalt through batch hydrothermal experiments using a brine that simulates reservoir conditions with 5 MPa CO 2 gas at 100 °C. When using basalt powders to evaluate reactivity, results show that although the leaching rates of elements (Mg, Al, Si, K, and Fe) from altered basalt were generally an order of magnitude lower than those from unaltered basalt in a CO 2 -saturated acidic environment, similar elemental leaching behavior was observed for the two basalt samples, with Ca and Mg having the highest leaching rates. However, in a more realistic environment simulated by block experiments, different leaching behaviors were observed. When the CO 2 -rich fluid reacts with altered basalt, rapid and preferential dissolution of smectite occurs, providing a significant amount of Mg to the solution, while Ca dissolution lags. This implies that when altered basalt is utilized for CO 2 mineralization, the carbonation step may differ from that of fresh basalt, with predominant Mg carbonation followed by Ca carbonation. This rapid dissolution of Mg suggests that altered basalt is a promising feedstock for CO 2 mineralization. This study provides theoretical support for developing technologies to utilize altered basalt for carbon storage.

Topics & Concepts

BasaltCarbonationDissolutionLeaching (pedology)Mineralization (soil science)GeochemistryGeologyHydrothermal circulationMineralogyChemistrySoil scienceSoil waterPhysical chemistrySeismologyOrganic chemistryCO2 Sequestration and Geologic InteractionsHigh-pressure geophysics and materialsGeothermal Energy Systems and Applications
Reactivity and Dissolution Characteristics of Naturally Altered Basalt in CO<sub>2</sub>-Rich Brine: Implications for CO<sub>2</sub> Mineralization | Litcius