Geomechanical models for induced seismicity in the Netherlands: inferences from simplified analytical, finite element and rupture model approaches

Wees, Jan-Diederik van; Fokker, P.A.; Thienen-Visser, K. van; Wassing, B.B.T.; Osinga, S.; Orlić, B.; Ghouri, Saad A.; Buijze, L.; Pluymaekers, Maarten

doi:10.1017/njg.2017.38

Cited by 22 publications

(32 citation statements)

References 29 publications

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“…Qualitatively, the results for regular slip in Figure c are in agreement with those found in earlier numerical studies; see, for example, Figures 7a, 7c, 7e, and 8a in Van Wees et al (), with the exception of one major difference: Van Wees et al () considered production rather than injection resulting in the occurrence of positive peak shear stresses at the internal corners of the reservoir and the fault (located at y =±100 m in our example), whereas for the injection case in Figure c the positive peak stresses occur at the external corners (i.e., at y =±200 m). This has potential consequences as will be discussed in the next section.…”

Section: Shear and Coulomb Stressessupporting

confidence: 91%

“…The linear elastic assumptions underlying the analytical solutions in our paper are restrictive, and a full analysis of the development of aseismic and seismic slip along the fault would require nonlinear quasi‐static and dynamic analyses, such as in Wassing et al (), Van Wees et al (), Buijze et al (). However, our linear elastic analytical results do give an indication of some typical features of the development of injection‐ or production‐induced seismic events in displaced faults as will be discussed below.…”

Section: Shear and Coulomb Stressesmentioning

confidence: 99%

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Insights From Closed‐Form Expressions for Injection‐ and Production‐Induced Stresses in Displaced Faults

Singhal

Vossepoel

2019

JGR Solid Earth

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We consider fluid-induced seismicity and present closed-form expressions for the elastic displacements, strains, and stresses resulting from injection into or production from a reservoir with displaced faults. We apply classic inclusion theory to two-dimensional finite-width and infinite-width reservoir models. First, we simplify the fault model to the bare minimum while still maintaining its essential features: a vertical fault in a homogeneous reservoir of infinite width in an infinite domain. We confirm and sharpen findings from earlier numerical studies and furthermore conclude that the development of infinitely large elastic shear stresses in a displaced fault, at the internal and external reservoir/fault corners, implies that even small amounts of injection or production will result in some amount of slip or other nonelastic deformation. Another finding is that there is a marked difference between the shear stress patterns resulting from injection and production in a reservoir with a displaced fault. In both situations two slip patches emerge but at the start of injection some amount of slip occurs immediately in the overburden and underburden, whereas during production the slip may remain inside the reservoir region. Next we derive similar but more complicated expressions for displaced inclined (normal or reverse) faults and conclude that our findings for vertical faults also apply to inclined faults.

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Section: Shear and Coulomb Stressessupporting

confidence: 91%

Section: Shear and Coulomb Stressesmentioning

confidence: 99%

Insights From Closed‐Form Expressions for Injection‐ and Production‐Induced Stresses in Displaced Faults

Singhal

Vossepoel

2019

JGR Solid Earth

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“…Stress concentrations play an important role also in some induced seismicity situations. Notably, in producing gas fields, peaked stresses can develop along the top or bottom of the intersection between the reservoir and a fault, due to the effect of differential compaction between reservoir compartments that are offset by the fault (Mulder, 2003;Buijze et al, 2017;Van Wees et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Initiation and arrest of earthquake ruptures due to elongated overstressed regions

Gális

Ampuero

Martin

et al. 2019

Geophysical Journal International

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The initiation of natural and induced earthquakes is promoted in fault areas where the shear stress is close to fault strength. In many important situations, these overstressed fault areas (or "asperities") are very elongated; for example, in the case of a fault intersecting a reservoir subject to fluid-injection, or the stress concentration along the bottom of a seismogenic zone induced by deep fault creep. Theoretical estimates of the minimum overstressed asperity size leading to runaway rupture and of the final size of self-arrested ruptures are only available for 2D problems and for 3D problems with an asperity aspect ratio close to one. In this study, we determine how the nucleation of ruptures on elongated asperities, and their ensuing arrest, depend on the size and aspect ratio of the asperity and on the background stress. Based on a systematic set of 3D dynamic rupture simulations assuming linear slip-weakening friction, we find that if the shortest asperity side is smaller than the 2D critical length, the problem effectively reduces to a 2D problem in which rupture nucleation and arrest are controlled by the shortest length of the asperity. Otherwise, nucleation and rupture arrest are controlled by the asperity area, with a minor exception: for asperities with shortest side slightly larger than the 2D critical length, arrested ruptures are smaller than predicted by the asperity area. The fact that rupture arrest is dominantly controlled by area, even for elongated asperities, corroborates the finding that observed maximum magnitudes of earthquakes induced by fluid injection are consistent with the theoretical relation between the magnitude of the largest self-arrested rupture and the injected volume (Galis et al., 2017). In context of induced seismicity, our simulations provide plausible scenarios that could be either favourable or challenging for traffic light systems, and provide mechanical insights into the conditions leading to these situations.

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“…Forecasting of induced seismicity requires a detailed understanding of both the physical mechanisms governing depletion-induced seismicity, as well as reservoir properties in time and space. On physical mechanisms, research from lab to field experiments and from experimental to complex numerical models has provided insights into the mechanisms behind induced seismicity in general [8][9][10][11][12], in particular depletion-induced seismicity [13][14][15][16][17][18][19] and injection-induced seismicity [20,21]. On reservoir properties, data acquisition efforts [22][23][24] can improve data quantity and quality, but as properties can only be measured directly in wells (which gives very limited spatial coverage) or using seismic reflection data (which needs to be interpreted, and has limits in applicability in regions with induced seismicity), these datasets carry large intrinsic uncertainties.…”

Section: Context and Background: Gas Production Induced Seismicitymentioning

confidence: 99%

Using machine learning for model benchmarking and forecasting of depletion-induced seismicity in the Groningen gas field

et al. 2021

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The Groningen gas field in the Netherlands is experiencing induced seismicity as a result of ongoing depletion. The physical mechanisms that control seismicity have been studied through rock mechanical experiments and combined physical-statistical models to support development of a framework to forecast induced-seismicity risks. To investigate whether machine learning techniques such as Random Forests and Support Vector Machines bring new insights into forecasts of induced seismicity rates in space and time, a pipeline is designed that extends time-series analysis methods to a spatiotemporal framework with a factorial setup, which allows probing a large parameter space of plausible modelling assumptions, followed by a statistical meta-analysis to account for the intrinsic uncertainties in subsurface data and to ensure statistical significance and robustness of results. The pipeline includes model validation using e.g. likelihood ratio tests against average depletion thickness and strain thickness baselines to establish whether the models have statistically significant forecasting power. The methodology is applied to forecast seismicity for two distinctly different gas production scenarios. Results show that seismicity forecasts generated using Support Vector Machines significantly outperform beforementioned baselines. Forecasts from the method hint at decreasing seismicity rates within the next 5 years, in a conservative production scenario, and no such decrease in a higher depletion scenario, although due to the small effective sample size no statistically solid statement of this kind can be made. The presented approach can be used to make forecasts beyond the investigated 5-years period, although this requires addition of limited physics-based constraints to avoid unphysical forecasts.

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Geomechanical models for induced seismicity in the Netherlands: inferences from simplified analytical, finite element and rupture model approaches

Cited by 22 publications

References 29 publications

Insights From Closed‐Form Expressions for Injection‐ and Production‐Induced Stresses in Displaced Faults

Insights From Closed‐Form Expressions for Injection‐ and Production‐Induced Stresses in Displaced Faults

Initiation and arrest of earthquake ruptures due to elongated overstressed regions

Using machine learning for model benchmarking and forecasting of depletion-induced seismicity in the Groningen gas field

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