TY - GEN
T1 - Induced Seismicity and Permeability Evolution in Gas Shales, CO2 Storage and Deep Geothermal Energy
AU - Elsworth, Derek
AU - Im, Kyunjae
AU - Fang, Yi
AU - Ishibashi, Takuya
AU - Wang, Chaoyi
N1 - Publisher Copyright:
© Springer Nature Singapore Pte Ltd. 2018.
PY - 2018
Y1 - 2018
N2 - Contemporary methods of energy conversions that reduce carbon intensity include sequestering CO2, fuel switching to lower-carbon sources, such as from gas shales, and recovering deep geothermal energy via EGS. In all of these endeavors, either maintaining the low permeability and integrity of caprocks or in controlling the growth of permeability in initially very-low-permeability shales and geothermal reservoirs represent key desires. At short-timescales of relevance, permeability is driven principally by deformations – in turn resulting from changes in total stresses, fluid pressure or thermal and chemical effects. These deformations may be intrinsically stable or unstable, result in aseismic or seismic deformation, with resulting changes in permeability conditioned by the deformational mode. We report observations, experiments and models to represent the respective roles of mineralogy, texture, scale and overpressures on the evolution of friction, stability and permeability in fractured rocks – and their interrelationships. The physics of these observed behaviors are explored via parametric studies and surface measurement of fractures, showing that both permeability and frictional strength are correlated to the fracture asperity evolution that is controlled in-turn by the sliding velocity and fracture material.
AB - Contemporary methods of energy conversions that reduce carbon intensity include sequestering CO2, fuel switching to lower-carbon sources, such as from gas shales, and recovering deep geothermal energy via EGS. In all of these endeavors, either maintaining the low permeability and integrity of caprocks or in controlling the growth of permeability in initially very-low-permeability shales and geothermal reservoirs represent key desires. At short-timescales of relevance, permeability is driven principally by deformations – in turn resulting from changes in total stresses, fluid pressure or thermal and chemical effects. These deformations may be intrinsically stable or unstable, result in aseismic or seismic deformation, with resulting changes in permeability conditioned by the deformational mode. We report observations, experiments and models to represent the respective roles of mineralogy, texture, scale and overpressures on the evolution of friction, stability and permeability in fractured rocks – and their interrelationships. The physics of these observed behaviors are explored via parametric studies and surface measurement of fractures, showing that both permeability and frictional strength are correlated to the fracture asperity evolution that is controlled in-turn by the sliding velocity and fracture material.
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U2 - 10.1007/978-981-13-0095-0_1
DO - 10.1007/978-981-13-0095-0_1
M3 - Conference contribution
AN - SCOPUS:85074579014
SN - 9789811300943
T3 - Proceedings of GeoShanghai 2018 International Conference: Multi-physics Processes in Soil Mechanics and Advances in Geotechnical Testing
SP - 1
EP - 20
BT - Proceedings of GeoShanghai 2018 International Conference
A2 - Hu, Liangbo
A2 - Gu, Xiaoqiang
A2 - Tao, Junliang
A2 - Zhou, Annan
PB - Springer
T2 - 4th GeoShanghai International Conference - Multi-physics Processes in Soil Mechanics and Advances in Geotechnical Testing, GSIC 2018
Y2 - 27 May 2018 through 30 May 2018
ER -