Key controls on the hydraulic properties of fault rocks in carbonates

Michie, Emma A. H.; Cooke, A.; Kaminskaite, I.; Stead, Jack; Plenderleith, Gayle; Tobiss, S.D.; Fisher, Q.J.; Yielding, Graham; Freeman, B.

doi:10.1144/petgeo2020-034

Cited by 4 publications

(1 citation statement)

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“…(1) Knowledge transfer from fossil fuel industry and sharing of data publicly (e.g., Erdlac, 2006;Bu et al, 2012;Groff et al, 2016): This should include the re-skilling and repurposing/ deployment of highly skilled and experienced oil and gas professionals, especially engineers and geologists; (2) Knowledge transfer from active decarbonisation plants around the world to allow optimization and sustainable implementation of technologies in other countries: Examples include storing CO 2 in basalt in the CarbFix Pilot Project in Iceland (Matter et al, 2009), geothermal energy plants such as Reykjanes, Krafla (Friðleifsson et al, 2015;Friðleifsson et al, 2019) or Larderello, Italy (Batini et al, 2003), and ATES at Eindhoven University of Technology in Netherlands (Kallesøe and Vangkilde-Pedersen, 2019); (3) Short and long term laboratory experiments: For instance, scaling experiments (e.g., Stáhl et al, 2000), porositypermeability measurements on fault rocks (e.g., Michie et al, 2020a;Michie et al, 2020b) coupled with in-depth microstructural studies (e.g., Kaminskaite et al, 2019;Kaminskaite et al, 2020); (4) Experiments at test sites, such as the UKGEOS coal mine geothermal test site in Glasgow, nuclear waste disposal sites in Olkiluoto, Finland (Siren, 2015), SKB in Sweden (Rosborg and Werme, 2008), Mont-Terri in Switzerland (Tsang et al, 2012), Mol-Dessel in Belgium (Desbois et al, 2010), and Bure and Tournemire in France (Armand et al, 2007;Matray et al, 2007). ( 5) Study of natural geological systems for long term behaviour and comparisons of predictions based on laboratory experiments coupled with numerical simulations: For instance, outcrops and/or core plugs taken out from natural geothermal systems where hydrothermal fluids have been flowing over long timescales (>10 2 -10 4 yrs) or fossil geothermal systems provide us with the examples of how hydrothermal fluids have affected the rocks on a large scale and how long the system has sustained the flow for (e.g., Major et al, 2018); (6) Numerical modelling using sophisticated and continuously improving codes, e.g.,: Microstructural modelling using hybrid approaches e.g., ELLE (Vass et al, 2014;Piazolo et al, 2019;Koehn et al, 2020) or codes f...…”

Section: Closing Knowledge Gapsmentioning

confidence: 99%

The Importance of Physiochemical Processes in Decarbonisation Technology Applications Utilizing the Subsurface: A Review

Kaminskaite¹,

Piazolo²,

Emery³

et al. 2022

Earth Sci. Syst. Soc.

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The Earth’s subsurface not only provides a wide range of natural resources but also contains large pore volume that can be used for storing both anthropogenic waste and energy. For example, geothermal energy may be extracted from hot water contained or injected into deep reservoirs and disused coal mines; CO2 may be stored within depleted petroleum reservoirs and deep saline aquifers; nuclear waste may be disposed of within mechanically stable impermeable strata; surplus heat may be stored within shallow aquifers or disused coal mines. Using the subsurface in a safe manner requires a fundamental understanding of the physiochemical processes which occur when decarbonising technologies are implemented and operated. Here, thermal, hydrological, mechanical and chemical perturbations and their dynamics need to be considered. Consequently, geoscience will play a central role in Society’s quest to reduce greenhouse gas emissions. This contribution provides a review of the physiochemical processes related to key technologies that utilize the subsurface for reducing greenhouse gas emissions and the resultant challenges associated with these technologies. Dynamic links between the geomechanical, geochemical and hydrological processes differ between technologies and the geology of the locations in which such technologies are deployed. We particularly focus on processes occurring within the lithologies most commonly considered for decarbonisation technologies. Therefore, we provide a brief comparison between the lithologies, highlighting the main advantages and disadvantages of each, and provide a list of key parameters and properties which have first order effects on the performance of specific rock types, and consequently should be considered during reservoir evaluation for decarbonising technology installation. The review identifies several key knowledge gaps that need to be filled to improve reservoir evaluation and performance prediction to be able to utilize the subsurface efficiently and sustainably. Most importantly, the biggest uncertainties emerge in prediction of fracture pattern development and understanding the extent and timescales of chemical reactions that occur within the decarbonising applications where external fluid or gas is cyclically injected and invariably causes disequilibrium within the system. Furthermore, it is clear that whilst geoscience can show us the opportunities to decarbonise our cities and industries, an interdisciplinary approach is needed to realize these opportunities, also involving social science, end-users and stakeholders.

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