Aftershock Triggering and Spatial Aftershock Zones in Fluid‐Driven Settings: Discriminating Induced Seismicity From Natural Swarms

Karimi, Kamran; Davidsen, Jörn

doi:10.1029/2020gl092267

Cited by 12 publications

(18 citation statements)

References 58 publications

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“…Broccardo et al, 2017;Mignan et al, 2017). The variations in seismicity rate are modulated by the hydraulic energy input rate, as expected for induced seismicity (Goebel et al, 2019;Langenbruch et al, 2011), but show no temporal clustering-in contrast to other fluid-driven settings (Karimi & Davidsen, 2021;Maghsoudi et al, 2018) as well as laboratory experiments and natural earthquakes (e.g., Davidsen & Kwiatek, 2013;Davidsen et al, 2021, and references therein). Neither the enhanced stressing rates due to fluid injection nor stress relaxation after the stimulation phases, nor the localization of seismicity within confined zones caused triggering.…”

Section: 𝐴𝐴mentioning

confidence: 61%

Limited earthquake interaction during a geothermal hydraulic stimulation in Helsinki, Finland

Kwiatek

Martínez‐Garzón

Davidsen

et al. 2022

Preprint

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Geothermal energy is considered an important and growing source of low-carbon-footprint energy. Development of deep Enhanced Geothermal Systems (EGS) using massive fluid injection (hydraulic fracturing) to improve reservoir permeability often leads to the occurrence of induced seismicity (e.g., Majer et al., 2012). Large earthquakes associated with anthropogenic fluid injection activities such as in Basel, Switzerland (e.g., Giardini, 2009)

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Section: 𝐴𝐴mentioning

confidence: 61%

Limited earthquake interaction during a geothermal hydraulic stimulation in Helsinki, Finland

Kwiatek

Martínez‐Garzón

Davidsen

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Broccardo et al., 2017; Mignan et al., 2017). The variations in seismicity rate are modulated by the hydraulic energy input rate, as expected for induced seismicity (Goebel et al., 2019; Langenbruch et al., 2011), but show no temporal clustering—in contrast to other fluid‐driven settings (Karimi & Davidsen, 2021; Maghsoudi et al., 2018) as well as laboratory experiments and natural earthquakes (e.g., Davidsen & Kwiatek, 2013; Davidsen et al., 2021, and references therein). Neither the enhanced stressing rates due to fluid injection nor stress relaxation after the stimulation phases, nor the localization of seismicity within confined zones caused triggering.…”

Section: Discussionmentioning

confidence: 70%

Limited Earthquake Interaction During a Geothermal Hydraulic Stimulation in Helsinki, Finland

et al. 2022

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We investigate induced seismicity associated with a hydraulic stimulation campaign performed in 2020 in the 5.8 km deep geothermal OTN‐2 well near Helsinki, Finland as part of the St1 Deep Heat project. A total of 2,875 m3 of fresh water was injected during 16 days at well‐head pressures <70 MPa and with flow rates between 400 and 1,000 L/min. The seismicity was monitored using a high‐resolution seismic network composed of 10 borehole geophones surrounding the project site and a borehole array of 10 geophones located in adjacent OTN‐3 well. A total of 6,121 induced earthquakes with local magnitudes MLnormalHnormalenormall>−1.9 ${M}_{\mathrm{L}}^{\mathrm{H}\mathrm{e}\mathrm{l}} > -1.9$ were recorded during and after the stimulation campaign. The analyzed statistical parameters include magnitude‐frequency b‐value, interevent time and interevent time ratio, as well as magnitude correlations. We find that the b‐value remained stationary for the entire injection period suggesting limited stress build‐up or limited fracture network coalescence in the reservoir. The seismicity during the stimulation neither shows signatures of magnitude correlations, nor temporal clustering or anticlustering beyond those arising from varying injection rates. The interevent time statistics are characterized by a Poissonian time‐varying distribution. The calculated parameters indicate no earthquake interaction. Focal mechanisms suggest that the injection activated a spatially distributed network of similarly oriented fractures. The seismicity displays stable behavior with no signatures pointing toward a runaway event. The cumulative seismic moment is proportional to the cumulative hydraulic energy and the maximum magnitude is controlled by injection rate. The performed study provides a base for implementation of time‐dependent probabilistic seismic hazard assessment for the project site.

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“…In the latter case, we remark that a change in S EFF sufficient to produce negative may be representative of a transition in seismic response and thus constitute a risk indicator. The observed cumulative seismic moment of earthquakes can include events that are induced by poroelastic stress, shear stress change due to mass change 8 , or possibly triggered by (dynamic or static) stress changes or afterslip arising from preceding events 43 , 44 . This could lead to a larger than predicted cumulative seismic moment, which only considers fluid induced arrested rupture.…”

Section: Resultsmentioning

confidence: 99%

Short-term forecasting of Mmax during hydraulic fracturing

Eaton

Davidsen

2022

Sci Rep

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Previous studies of injection-induced earthquake sequences have shown that the maximum magnitude (Mmax) of injection-induced seismicity increases with the net injected volume (V); however, different proposed seismic-hazard paradigms predict significantly different values of Mmax. Using injection and seismicity data from two project areas in northeastern British Columbia, Canada, where hydraulic fracturing induced seismicity was observed, we test the predictive power and robustness of three existing and one novel method to estimate Mmax. Due to their vastly different values of seismogenic index (Σ), these two project areas represent end-member cases of seismogenic response. Our novel method progressively adjusts the Mmax forecast under the assumption that each recorded event embodies an incremental release of fluid-induced stress. The results indicate that our method typically provides the lowest upper bound of the tested methods and it is less sensitive to site-specific calibration parameters such as Σ. This makes the novel method appealing for operational earthquake forecasting schemes as a real-time mitigation strategy to manage the risks of induced seismicity.

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Aftershock Triggering and Spatial Aftershock Zones in Fluid‐Driven Settings: Discriminating Induced Seismicity From Natural Swarms

Cited by 12 publications

References 58 publications

Limited earthquake interaction during a geothermal hydraulic stimulation in Helsinki, Finland

Limited earthquake interaction during a geothermal hydraulic stimulation in Helsinki, Finland

Limited Earthquake Interaction During a Geothermal Hydraulic Stimulation in Helsinki, Finland

Short-term forecasting of Mmax during hydraulic fracturing

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