CO2 mineral trapping in fractured basalt

CO2 mineral trapping in fractured basalt

Fractures in basalt can provide substantial surface area for reactions, and limited mass transfer in fractures can allow accumulation of cations to form carbonate minerals in geologic carbon sequestration. In this study, flood basalt and serpentinized basalt with engineered fractures were reacted in...

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Veröffentlicht in:International journal of greenhouse gas control 2017-11, Vol.66 (C), p.204-217
Hauptverfasser: Xiong, Wei, Wells, Rachel K., Menefee, Anne H., Skemer, Philip, Ellis, Brian R., Giammar, Daniel E.
Format: Artikel
Sprache:eng
Schlagworte:
Energy & Fuels
Engineering
ENVIRONMENTAL SCIENCES
Fractured basalt
Geologic carbon sequestration
Reactive transport modeling
Science & Technology - Other Topics
Siderite
X-ray μCT segmentation
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Zusammenfassung:Fractures in basalt can provide substantial surface area for reactions, and limited mass transfer in fractures can allow accumulation of cations to form carbonate minerals in geologic carbon sequestration. In this study, flood basalt and serpentinized basalt with engineered fractures were reacted in water equilibrated with 10 MPa CO2 at 100 °C or 150 °C for up to 40 weeks. Carbonation in basalt fractures was observed as early as 6 weeks, with Mg- and Ca-bearing siderite formed in both basalts reacted at 100 °C and Mg-Fe-Ca carbonate minerals formed in the flood basalt reacted at 150 °C. X-ray μCT segmentation revealed that precipitates filled 5.4% and 15% (by volume) of the flood basalt fracture after 40 weeks of reaction at 100 °C and 150 °C, respectively. Zones of elevated carbonate abundance did not completely seal the fracture. Limited siderite clusters (
ISSN:1750-5836
1878-0148
DOI:10.1016/j.ijggc.2017.10.003