Litcius/Paper detail

Laboratory experiments of carbon mineralization potential of the main terrestrial basalt reservoirs in China

Yanning Pan, Yunhua Liu, Zengqian Hou, Qiang Sun, Nianzhi Jiao, Guochen Dong, Jihua Liu, Gaoxue Yang, Huiting Zhang, Hailiang Jia, Hao Huang

2024Geoscience Frontiers7 citationsDOIOpen Access PDF

Abstract

• The precipitation of rhombohedral calcite is observed in CO 2 -H 2 O/brine- basalt at low temperatures (≤35℃). • Alkaline minerals in basalt, nepheline and Na-sanidine, promote the formation of calcite. • Basalt from Shandong Linqu-Changle volcanic basin exhibits the highest rate of carbonation. Against the background of realizing the goal of “carbon peaking and carbon neutrality”, using basaltic rocks for carbon mineralization is one of the most promising approaches to reduce the rise in atmospheric CO 2 concentrations. This study conducted a series of experiments to assess carbon mineralization in nine basalt samples from the main terrestrial basalt reservoirs in China within CO 2 -H 2 O/brine-rock systems at low temperatures (≤35 °C). The results indicate that the secondary carbonates formed in the CO 2 -H 2 O/brine-basalt system are predominantly calcite rather than Mg-carbonate minerals at low temperatures (≤35 °C). Hence, at low temperatures (≤35 °C), basalt rich in Ca-bearing minerals promotes the formation of stable carbonate minerals more effectively than basalt containing Mg-bearing minerals. Furthermore, under conditions of low temperatures (≤35 °C) and pressures of approximately 3 MPa, the results suggest that alkaline olivine basalt, with a higher content of Ca-minerals and typical alkaline minerals (nepheline and Na-sanidine), exhibits the highest pH value and the highest amount of calcite. Hence, the alkaline minerals, nepheline and Na-sanidine, serve as pH buffers to increase the pH and promote the precipitation of calcite within CO 2 -H 2 O– basalt systems at low temperatures (≤35 °C). Among the nine evaluated basalts, basalt from the Shandong Linqu-Changle volcanic basin exhibits the highest rate of carbon mineralization at low temperatures (≤35 °C). Hence, Cenozoic alkaline olivine basalt from Shandong Linqu-Changle volcanic basin is one of the most promising basalt reservoirs in China for future in- situ carbonation. As for ex- situ carbonation, compared with olivine, diopside or Ca-plagioclase may be more appropriate for increasing ocean negative emissions.

Topics & Concepts

BasaltMineralization (soil science)Earth scienceChinaGeochemistryGeologyCarbon cycleTerrestrial ecosystemCarbon fibersEcosystemSoil scienceEcologySoil waterGeographyBiologyMaterials scienceComposite numberComposite materialArchaeologyCO2 Sequestration and Geologic InteractionsMethane Hydrates and Related PhenomenaGeological and Geochemical Analysis