Self-sealing mafic sills for carbon and hydrogen storage

Tabular igneous intrusions (sills) are common features in sedimentary basins and have the potential to be useful seals for fluids (e.g. CO2 or H2) in geological storage scenarios, and may be important as the need for geological carbon sequestration and alternative fuel storage increases. This is adv...

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Veröffentlicht in:Enabling Secure Subsurface Storage in Future Energy Systems 2023-08, Vol.528 (1), p.359-376
Hauptverfasser: Schmitt, Rhiannon R., Andrews, Graham D. M., Moore, Jonathan, Paronish, Thomas, Workman, Scott, Gumowski, Layne M., Brown, Sarah R., Crandall, Dustin, Neubaum, John
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Sprache:eng
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Zusammenfassung:Tabular igneous intrusions (sills) are common features in sedimentary basins and have the potential to be useful seals for fluids (e.g. CO2 or H2) in geological storage scenarios, and may be important as the need for geological carbon sequestration and alternative fuel storage increases. This is advantageous in regions without ready access to large-volume reservoirs in depleted hydrocarbon plays and saline aquifers, such as the northeastern USA. Moreover, geological H2 storage requires more demanding conditions than those typically associated with oil and gas. An enhanced seal will have the properties of a traditional seal – competent, low permeability and laterally extensive – with the addition of being able to self-seal pre-existing and induced fractures. Self-sealing will occur along fluid pathways like fractures where CO2, water and minerals like plagioclase, olivine and pyroxene react together. Dolerite sills from the Gettysburg Basin, Pennsylvania, have remarkably low permeability and homogeneous compositions that include minerals that will readily react with CO2 dissolved in water. Here, we characterize the physical properties and chemical gradients within several mafic sills cored in five boreholes. In addition, preliminary CO2-reaction experiments on dolerite samples demonstrated rapid carbonate mineralization.
ISSN:0305-8719
2041-4927
DOI:10.1144/SP528-2022-43