This is a Preprint and has not been peer reviewed. The published version of this Preprint is available: https://doi.org/10.55575/tektonika2023.1.1.11. This is version 2 of this Preprint.
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Abstract
The fundamental properties of salt have long been exploited in the search for hydrocarbons, as they influence many of the hydrocarbon play elements. This industrial application has driven the pursuit of salt tectonic knowledge over the last century and led to major conceptual advances in the field. However, the current need, and social-political demand, to decarbonize suggests that the applicability of salt tectonic knowledge will expand to other aspects of the subsurface that are relevant to the energy transition. The pace of this change leaves the field of salt tectonics grappling with a fundamental question – what role does salt tectonics have as part of the energy transition? Here, we discuss the role salt tectonics can play in a number of key energy transition technologies, namely, energy storage as gas in salt caverns (e.g. hydrogen and compressed air), CO2 storage, and geothermal energy. For each of these technologies we explore: i) fundamental concepts and driving forces; ii) how and why the properties of salt are of importance; and iii) the key salt-related technical challenges, potential future research directions, and technical approaches needed for large-scale development.
We highlight how salt basins offer vast potential for development throughout the energy transition including, but not limited to: i) the likely demand for thousands of new hydrogen storage caverns inside salt bodies by 2050; ii) a likely early focus for porous media CO2 storage sites in basins strongly influenced by salt tectonics; and iii) enhanced geothermal energy potential in and around salt bodies. Effective exploitation of these resources will require a deeper understanding of the internal composition, geometry, and evolution of salt structures and their surrounding sediments, and potentially the development of more predictive models of salt tectonic behaviour. Critically, we see the need to integrate learnings of salt tectonics gained in the academic, mining, solution mining, and oil and gas communities, and apply a fresh perspective to answer research questions of relevance to the energy transition. Developing this new understanding will help optimise design, reduce geotechnical risk, and improve efficiency for energy transition technologies, thus indicating a strong future demand for salt tectonic research.
DOI
https://doi.org/10.31223/X5363J
Subjects
Physical Sciences and Mathematics
Keywords
and potentially the development of more predictive models of salt tectonic behaviour. Critically, oil and gas, Geothermal, CCUS, salt caverns, Hydrogen Storage, Energy Transition, salt tectonics, thus indicating a strong future demand for salt tectonic research., and improve efficiency for energy transition technologies, reduce geotechnical risk, and apply a fresh perspective to answer research questions of relevance to the energy transition. Developing this new understanding will help optimise design, and oil and gas communities, solution mining, mining, we see the need to integrate learnings of salt tectonics gained in the academic, The fundamental properties of salt have long been exploited in the search for hydrocarbons, and evolution of salt structures and their surrounding sediments, geometry, but not limited to: i) the likely demand for thousands of new hydrogen storage caverns inside salt bodies by 2050; ii) a likely early focus for porous media CO2 storage sites in basins strongly influ, and technical approaches needed for large-scale development. We highlight how salt basins offer vast potential for development throughout the energy transition including, potential future research directions, and geothermal energy. For each of these technologies we explore: i) fundamental concepts and driving forces; ii) how and why the properties of salt are of importance; and iii) the key salt-related t, CO2 storage, energy storage as gas in salt caverns (e.g. hydrogen and compressed air), namely, we discuss the role salt tectonics can play in a number of key energy transition technologies, to decarbonize suggests that the applicability of salt tectonic knowledge will expand to other aspects of the subsurface that are relevant to the energy transition. The pace of this change leaves the, and social-political demand, the current need, as they influence many of the hydrocarbon play elements. This industrial application has driven the pursuit of salt tectonic knowledge over the last century and led to major conceptual advances in th
Dates
Published: 2022-07-07 04:12
Last Updated: 2022-07-09 07:33
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License
CC BY Attribution 4.0 International
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Conflict of interest statement:
None
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None - this is a review paper
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