Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale
Fluid injection-induced earthquakes involve a series of complex physical processes. Evaluating these processes at the basin scale requires an amount of input data and a super computational ability to solve in near-real time risk analysis, which remains the most critical challenge in geo-energy related applications. Although the current computational tools can achieve a good simulation for the field scale problems, they are far away from the requirements of the basin scale analysis. Alternatively, we can apply verified analytical solutions of certain processes to speed the whole calculations when moving from the field to the basin scale. With this in mind, we adopt the analytical solutions for pore pressure diffusion and stress variations due to fluid injection into the reservoir. With the superposition principle, the analytical solutions can address the coupling problem of multi-injection wells at the basin scale. We then assess faults stability and the associated induced seismicity potential using the hydro-mechanical perturbations throughout the basin computed analytically. To handle the uncertainty of geological properties, including the fault and reservoir geometries, hydraulic and mechanical properties, we perform Monte Carlo simulations to analyze their effects on induced seismicity potential. Such comprehensive parametric space analysis currently represents an insurmountable obstacle to be solved numerically, even calculating the problem in parallel. We propose a feasible methodology to mitigate the magnitude of induced seismicity, and even to avoid large earthquakes for subsurface energy-related projects, based on the results obtained both at the field and basin scales. This development will represent a great tool for risk evaluation of induced earthquakes not only in the period of site selection, but also in the whole lifetime of geo-energy projects.
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| Format: | comunicación de congreso biblioteca |
| Language: | English |
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2023-05
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| Subjects: | Geothermal energy, Induced seismicity, Ensure access to affordable, reliable, sustainable and modern energy for all, |
| Online Access: | http://hdl.handle.net/10261/311470 |
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dig-idaea-es-10261-3114702023-06-14T11:15:11Z Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale Wu, Haiqing Xie, Jian Vilarrasa, Víctor Geothermal energy Induced seismicity Ensure access to affordable, reliable, sustainable and modern energy for all Fluid injection-induced earthquakes involve a series of complex physical processes. Evaluating these processes at the basin scale requires an amount of input data and a super computational ability to solve in near-real time risk analysis, which remains the most critical challenge in geo-energy related applications. Although the current computational tools can achieve a good simulation for the field scale problems, they are far away from the requirements of the basin scale analysis. Alternatively, we can apply verified analytical solutions of certain processes to speed the whole calculations when moving from the field to the basin scale. With this in mind, we adopt the analytical solutions for pore pressure diffusion and stress variations due to fluid injection into the reservoir. With the superposition principle, the analytical solutions can address the coupling problem of multi-injection wells at the basin scale. We then assess faults stability and the associated induced seismicity potential using the hydro-mechanical perturbations throughout the basin computed analytically. To handle the uncertainty of geological properties, including the fault and reservoir geometries, hydraulic and mechanical properties, we perform Monte Carlo simulations to analyze their effects on induced seismicity potential. Such comprehensive parametric space analysis currently represents an insurmountable obstacle to be solved numerically, even calculating the problem in parallel. We propose a feasible methodology to mitigate the magnitude of induced seismicity, and even to avoid large earthquakes for subsurface energy-related projects, based on the results obtained both at the field and basin scales. This development will represent a great tool for risk evaluation of induced earthquakes not only in the period of site selection, but also in the whole lifetime of geo-energy projects. Peer reviewed 2023-06-14T11:15:10Z 2023-06-14T11:15:10Z 2023-05 comunicación de congreso Solid Earth and Geohazards in the Exascale Era, Galileo Conference, Barcelona, Spain, 23-26 May 2023 http://hdl.handle.net/10261/311470 10.5194/egusphere-gc11-solidearth-27 en Publisher's version https://doi.org/10.5194/egusphere-gc11-solidearth-27 Sí open |
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Geothermal energy Induced seismicity Ensure access to affordable, reliable, sustainable and modern energy for all Geothermal energy Induced seismicity Ensure access to affordable, reliable, sustainable and modern energy for all |
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Geothermal energy Induced seismicity Ensure access to affordable, reliable, sustainable and modern energy for all Geothermal energy Induced seismicity Ensure access to affordable, reliable, sustainable and modern energy for all Wu, Haiqing Xie, Jian Vilarrasa, Víctor Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale |
| description |
Fluid injection-induced earthquakes involve a series of complex physical processes. Evaluating these processes at the basin scale requires an amount of input data and a super computational ability to solve in near-real time risk analysis, which remains the most critical challenge in geo-energy related applications. Although the current computational tools can achieve a good simulation for the field scale problems, they are far away from the requirements of the basin scale analysis. Alternatively, we can apply verified analytical solutions of certain processes to speed the whole calculations when moving from the field to the basin scale. With this in mind, we adopt the analytical solutions for pore pressure diffusion and stress variations due to fluid injection into the reservoir. With the superposition principle, the analytical solutions can address the coupling problem of multi-injection wells at the basin scale. We then assess faults stability and the associated induced seismicity potential using the hydro-mechanical perturbations throughout the basin computed analytically.
To handle the uncertainty of geological properties, including the fault and reservoir geometries, hydraulic and mechanical properties, we perform Monte Carlo simulations to analyze their effects on induced seismicity potential. Such comprehensive parametric space analysis currently represents an insurmountable obstacle to be solved numerically, even calculating the problem in parallel. We propose a feasible methodology to mitigate the magnitude of induced seismicity, and even to avoid large earthquakes for subsurface energy-related projects, based on the results obtained both at the field and basin scales. This development will represent a great tool for risk evaluation of induced earthquakes not only in the period of site selection, but also in the whole lifetime of geo-energy projects. |
| format |
comunicación de congreso |
| topic_facet |
Geothermal energy Induced seismicity Ensure access to affordable, reliable, sustainable and modern energy for all |
| author |
Wu, Haiqing Xie, Jian Vilarrasa, Víctor |
| author_facet |
Wu, Haiqing Xie, Jian Vilarrasa, Víctor |
| author_sort |
Wu, Haiqing |
| title |
Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale |
| title_short |
Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale |
| title_full |
Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale |
| title_fullStr |
Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale |
| title_full_unstemmed |
Risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale |
| title_sort |
risk assessment and mitigation of induced seismicity for geo-energy related applications at the basin scale |
| publishDate |
2023-05 |
| url |
http://hdl.handle.net/10261/311470 |
| work_keys_str_mv |
AT wuhaiqing riskassessmentandmitigationofinducedseismicityforgeoenergyrelatedapplicationsatthebasinscale AT xiejian riskassessmentandmitigationofinducedseismicityforgeoenergyrelatedapplicationsatthebasinscale AT vilarrasavictor riskassessmentandmitigationofinducedseismicityforgeoenergyrelatedapplicationsatthebasinscale |
| _version_ |
1781881372490596352 |