Geologic influence on induced seismicity: Constraints from potential field data in Oklahoma

Shah, Anjana K.; Keller, G. Randy

doi:10.1002/2016gl071808

Cited by 46 publications

(43 citation statements)

References 27 publications

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“…Corresponding magnetic gradients highlight linear features that in some areas correspond to major mapped faults (Jones & Lyons, 1964;Luza & Lawson, 1982;Shah & Keller, 2017). Combining these data gravity and drill data reveals a relation between seismicity and interpreted lithology, where most earthquakes appear to occur in fractured intrusive rocks (Shah & Keller, 2017), especially the central Oklahoma granite and Spavinaw granite groups described by Denison (1981) and areas in northwestern Oklahoma believed to contain intrusive rocks associated with the midcontinent rift. There is also a lack of seismicity in areas marked by intrusions associated with relatively smooth magnetic anomalies such as the Cleveland magnetic anomaly ( Figure S1), attributed to a lack of major faults that might serve as fluid pathways.…”

Section: Geologic Backgroundmentioning

confidence: 60%

Aeromagnetic Data Reveal Potential Seismogenic Basement Faults in the Induced Seismicity Setting of Oklahoma

Shah

Crain

2018

Geophysical Research Letters

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New aeromagnetic survey data collected over north central Oklahoma image possible seismogenic faults in the crystalline basement. Linear earthquake sequences associated with induced seismicity suggest the reactivation of ancient basement faults, but few of these sequences are aligned with mapped faults. The new data show many earthquake sequences aligned with linear magnetic gradients or offsets between anomalies, while mapped faults, which mainly describe sedimentary cover, show limited correspondence with either. This strongly suggests significant structural differences between the crystalline basement and sedimentary cover. Furthermore, while the earthquakes are occurring on reactivated ancient faults, most of these faults have likely been inactive for millions of years. The magnetic data exhibit many gradient lineaments that are optimally oriented for fault slip, and the earthquake data suggest additional optimally oriented faults. Together these data suggest the presence of potentially numerous seismogenic faults throughout the region, which may contribute to high levels of induced seismicity.

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Section: Geologic Backgroundmentioning

confidence: 60%

Aeromagnetic Data Reveal Potential Seismogenic Basement Faults in the Induced Seismicity Setting of Oklahoma

Shah

Crain

2018

Geophysical Research Letters

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“…As observed in the CM2‐linked earthquakes, migration fronts of injection‐induced seismicity show commonly a dominant updip component coherently with the migration attitude of pressurized fluids along preferential pathways (Cox, ). Nevertheless, downward migration of seismicity and deep sequences in the basement rocks have been reported and related to the strong hydrological control exerted by deep seated large faults that promote pressure channeling effects under the injection formations (Chang & Segall, ; Goebel et al, ; Keranen et al, ; McNamara et al, ; Shah & Keller, ). Seismicity linked to well CM2 has a cutoff depth of 4.5–5.0 km (Figures a, b, and ).…”

Section: Discussionmentioning

confidence: 99%

“…Pore fluid pressure changes induced by high‐rate disposal wells can trigger noticeable seismicity at great distances (> 10 km) from injection sites (Yeck et al, ) and at significantly greater depths than those of the formations where fluids are disposed (Horton, ; Keranen et al, ). In such cases, high permeable fault zones play a key role in triggering large earthquakes because they can transmit pore pressure perturbations and channel fluid flow over large distances from high‐rate wells to critically stressed basement faults (Shah & Keller, , and references therein). Therefore, a better understanding of the reservoir where fluids are injected and the identification of structures that may channel pore pressure diffusion and fluid migration toward large active faults are fundamental issues for a safe management of disposal activity.…”

Section: Introductionmentioning

confidence: 99%

Reservoir Structure and Wastewater‐Induced Seismicity at the Val d'Agri Oilfield (Italy) Shown by Three‐Dimensional V_p and V_p/V_s Local Earthquake Tomography

et al. 2017

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Wastewater injection into a high‐rate well in the Val d'Agri oilfield, the largest in onshore Europe, has induced swarm microseismicity since the initiation of disposal in 2006. To investigate the reservoir structure and to track seismicity, we performed a high‐spatial resolution local earthquake tomography using 1,281 natural and induced earthquakes recorded by local networks. The properties of the carbonate reservoir (rock fracturing, pore fluid pressure) and inherited faults control the occurrence and spatiotemporal distribution of seismicity. A low‐Vp, high‐Vp/Vs region under the well represents a fluid saturated fault zone ruptured by induced seismicity. High‐Vp, high‐Vp/Vs bumps match reservoir culminations indicating saturated liquid‐bearing zones, whereas a very low Vp, low Vp/Vs anomaly might represent a strongly fractured and depleted zone of the hydrocarbon reservoir characterized by significant fluid withdrawal. The comprehensive picture of the injection‐linked seismicity obtained by integrating reservoir‐scale tomography, high‐precision earthquake locations, and geophysical and injection data suggests that the driving mechanism is the channeling of pore pressure perturbations through a high permeable fault damage zone within the reservoir. The damage zone surrounds a Pliocene reverse fault optimally oriented in the current extensional stress field. The ruptured damage zone measures 2 km along strike and 3 km along dip and is confined between low permeability ductile formations. Injection pressure is the primary parameter controlling seismicity rate. Our study underlines that local earthquake tomography also using wastewater‐induced seismicity can give useful insights into the physical mechanism leading to these earthquakes.

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“…However, in some cases, geological proxies (e.g., Eaton, 2017;Schultz et al, 2016;Shah & Keller, 2016;Brudzinski et al, 2016) have been successfully used to provide first-order explanations of potential induced seismicity locations. However, in some cases, geological proxies (e.g., Eaton, 2017;Schultz et al, 2016;Shah & Keller, 2016;Brudzinski et al, 2016) have been successfully used to provide first-order explanations of potential induced seismicity locations.…”

Section: Introductionmentioning

confidence: 99%

The Geological Susceptibility of Induced Earthquakes in the Duvernay Play

Pawley¹,

Schultz²,

Playter³

et al. 2018

Geophysical Research Letters

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Presently, consensus on the incorporation of induced earthquakes into seismic hazard has yet to be established. For example, the nonstationary, spatiotemporal nature of induced earthquakes is not well understood. Specific to the Western Canada Sedimentary Basin, geological bias in seismogenic activation potential has been suggested to control the spatial distribution of induced earthquakes regionally. In this paper, we train a machine learning algorithm to systemically evaluate tectonic, geomechanical, and hydrological proxies suspected to control induced seismicity. Feature importance suggests that proximity to basement, in situ stress, proximity to fossil reef margins, lithium concentration, and rate of natural seismicity are among the strongest model predictors. Our derived seismogenic potential map faithfully reproduces the current distribution of induced seismicity and is suggestive of other regions which may be prone to induced earthquakes. The refinement of induced seismicity geological susceptibility may become an important technique to identify significant underlying geological features and address induced seismic hazard forecasting issues.

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Geologic influence on induced seismicity: Constraints from potential field data in Oklahoma

Cited by 46 publications

References 27 publications

Aeromagnetic Data Reveal Potential Seismogenic Basement Faults in the Induced Seismicity Setting of Oklahoma

Aeromagnetic Data Reveal Potential Seismogenic Basement Faults in the Induced Seismicity Setting of Oklahoma

Reservoir Structure and Wastewater‐Induced Seismicity at the Val d'Agri Oilfield (Italy) Shown by Three‐Dimensional V_p and V_p/V_s Local Earthquake Tomography

The Geological Susceptibility of Induced Earthquakes in the Duvernay Play

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Geologic influence on induced seismicity: Constraints from potential field data in Oklahoma

Cited by 46 publications

References 27 publications

Aeromagnetic Data Reveal Potential Seismogenic Basement Faults in the Induced Seismicity Setting of Oklahoma

Aeromagnetic Data Reveal Potential Seismogenic Basement Faults in the Induced Seismicity Setting of Oklahoma

Reservoir Structure and Wastewater‐Induced Seismicity at the Val d'Agri Oilfield (Italy) Shown by Three‐Dimensional Vp and Vp/Vs Local Earthquake Tomography

The Geological Susceptibility of Induced Earthquakes in the Duvernay Play

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Resources

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Reservoir Structure and Wastewater‐Induced Seismicity at the Val d'Agri Oilfield (Italy) Shown by Three‐Dimensional V_p and V_p/V_s Local Earthquake Tomography