From checking deterministic predictions to probabilities, scenarios and control loops for regulatory supervision

Waal, J.A. de; Muntendam-Bos, A.G.; Roest, J. P. A.

doi:10.1017/njg.2017.15

Cited by 5 publications

(4 citation statements)

References 15 publications

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“…The history of Mmax estimates for the Groningen field is worth briefly summarising. The earliest estimate was made by a body called Begeleidingscommissie Onderzoek Aardbevingen (BOA, Advisory Committee on Earthquake Investigation), which in 1993 issued a report that estimated Mmax as being in the range 2.9 to 3.3 (de Waal et al, 2017), although it should be noted that this was not specifically for the Groningen field but rather for earthquakes around Assen, south of the Groningen field. KNMI subsequently issued new estimates in 1995, for which two approaches were used: the first was based on the cumulative trend of released seismic energy, which yielded an Mmax of 3.3; the second was based on the dimensions of geological faults, which gave an Mmax of 3.5.…”

Section: Modelling Seismic Hazard and Riskmentioning

confidence: 99%

Earthquake hazard and risk analysis for natural and induced seismicity: towards objective assessments in the face of uncertainty

Bommer

2022

Bull Earthquake Eng

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The fundamental objective of earthquake engineering is to protect lives and livelihoods through the reduction of seismic risk. Directly or indirectly, this generally requires quantification of the risk, for which quantification of the seismic hazard is required as a basic input. Over the last several decades, the practice of seismic hazard analysis has evolved enormously, firstly with the introduction of a rational framework for handling the apparent randomness in earthquake processes, which also enabled risk assessments to consider both the severity and likelihood of earthquake effects. The next major evolutionary step was the identification of epistemic uncertainties related to incomplete knowledge, and the formulation of frameworks for both their quantification and their incorporation into hazard assessments. Despite these advances in the practice of seismic hazard analysis, it is not uncommon for the acceptance of seismic hazard estimates to be hindered by invalid comparisons, resistance to new information that challenges prevailing views, and attachment to previous estimates of the hazard. The challenge of achieving impartial acceptance of seismic hazard and risk estimates becomes even more acute in the case of earthquakes attributed to human activities. A more rational evaluation of seismic hazard and risk due to induced earthquakes may be facilitated by adopting, with appropriate adaptations, the advances in risk quantification and risk mitigation developed for natural seismicity. While such practices may provide an impartial starting point for decision making regarding risk mitigation measures, the most promising avenue to achieve broad societal acceptance of the risks associated with induced earthquakes is through effective regulation, which needs to be transparent, independent, and informed by risk considerations based on both sound seismological science and reliable earthquake engineering.

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Section: Modelling Seismic Hazard and Riskmentioning

confidence: 99%

Earthquake hazard and risk analysis for natural and induced seismicity: towards objective assessments in the face of uncertainty

Bommer

2022

Bull Earthquake Eng

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“…This partitioning directly controls the evolution of compaction and hence surface subsidence during production (Mallman & Zoback, 2007;Schutjens et al, 1995), and the stresses (Buijze et al, 2017) and elastic energy available to drive induced seismicity and associated energy dissipating processes occurring upon fault rupture (Cooke & Madden, 2014;Mcgarr, 1999;Shipton et al, 2013). In recent years, the onset of significant induced seismicity in strongly depleted reservoirs, such as the large Groningen field in the NE Netherlands (Grotsch et al, 2011), has created an urgent need to understand these effects much better (e.g., de Waal et al, 2017;Spiers et al, 2017). This paper addresses this need.…”

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confidence: 99%

Deformation Behavior of Sandstones From the Seismogenic Groningen Gas Field: Role of Inelastic Versus Elastic Mechanisms

et al. 2018

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Reduction of pore fluid pressure in sandstone oil, gas, or geothermal reservoirs causes elastic and possibly inelastic compaction of the reservoir, which may lead to surface subsidence and induced seismicity. While elastic compaction is well described using poroelasticity, inelastic and especially time‐dependent compactions are poorly constrained, and the underlying microphysical mechanisms are insufficiently understood. To help bridge this gap, we performed conventional triaxial compression experiments on samples recovered from the Slochteren sandstone reservoir in the seismogenic Groningen gas field in the Netherlands. Successive stages of active loading and stress relaxation were employed to study the partitioning between elastic versus time‐independent and time‐dependent inelastic deformations upon simulated pore pressure depletion. The results showed that inelastic strain developed from the onset of compression in all samples tested, revealing a nonlinear strain hardening trend to total axial strains of 0.4 to 1.3%, of which 0.1 to 0.8% were inelastic. Inelastic strains increased with increasing initial porosity (12–25%) and decreasing strain rate (10−5 s−1 to 10−9 s−1). Our results imply a porosity and rate‐dependent yield envelope that expands with increasing inelastic strain from the onset of compression. Microstructural evidence indicates that inelastic compaction was controlled by a combination of intergranular cracking, intergranular slip, and intragranular/transgranular cracking with intragranular/transgranular cracking increasing in importance with increasing porosity. The results imply that during pore pressure reduction in the Groningen field, the assumption of a poroelastic reservoir response leads to underestimation of the change in the effective horizontal stress and overestimation of the energy available for seismicity.

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“…Earthquakes with magnitudes of M 1.8 and higher are reported to be felt by people, whereas earthquakes with magnitudes of M 2.0 and higher have caused nonstructural damage to buildings (e.g., cracks) (de Waal et al, 2017). In the beginning of the 1990s, the maximum expected magnitude was estimated around M 3.0, however this value was systematically raised to about M 4.0 prior to the 2012 Huizinge earthquake and M 5.0 after the Huizinge earthquake (de Waal et al, 2017).…”

Section: Induced Seismicitymentioning

confidence: 93%

The Groningen Case: When Science Becomes Part of the Problem, Not the Solution

Sintubin

2018

Seismological Research Letters

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From checking deterministic predictions to probabilities, scenarios and control loops for regulatory supervision

Cited by 5 publications

References 15 publications

Earthquake hazard and risk analysis for natural and induced seismicity: towards objective assessments in the face of uncertainty

Earthquake hazard and risk analysis for natural and induced seismicity: towards objective assessments in the face of uncertainty

Deformation Behavior of Sandstones From the Seismogenic Groningen Gas Field: Role of Inelastic Versus Elastic Mechanisms

The Groningen Case: When Science Becomes Part of the Problem, Not the Solution

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