Earthquake-induced crustal deformation and consequences for fault displacement hazard analysis of nuclear power plants

Gürpinar³

2019

Earthquake Spectra

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We performed a review of a representative data set on coseismic surface deformation, derived from both interferometric synthetic aperture radar imaging and from a traditional field survey of surface faulting. This analysis indicates a minimum threshold value of M w 5.4–5.5 for earthquake-induced ground deformation and faulting, with an inherently lower limit of detection that makes it hard to recognize surface deformation caused by M w < 4.5–5.0 events. Significant exceptions are represented by shallow (i.e., less than circa 5 km) events that occur in volcano-tectonic settings, where surface deformation and dislocation are also clearly detectable for M w circa 4.0. Furthermore, a statistically significant regression between the areal extent of surface deformation and maximum slip at surface is proposed. This correlation is discussed in relation to fault displacement hazard analysis for nuclear power plants. In particular, the deformation area is used to find a potential solution for the second and third criterion for defining a capable fault.

Section: Introductionmentioning

confidence: 54%

Section: Discussionmentioning

confidence: 75%

Section: Lower Limit Of Mw For Earthquake-induced Ground Deformation: Insights From Insar Imagingmentioning

confidence: 99%

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Surface Faulting and Ground Deformation: Considerations on Their Lower Detectable Limit and on FDHA for Nuclear Installations

Serva

Gürpinar³

2019

Earthquake Spectra

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“…The position at the surface of the antithetic structure is driven by factors such as the change in dip of the principal fault at depth (e.g., Caskey et al, 1996); this points to the possibility of introducing deterministic constraints in the estimation of the expected distributed faulting. Thus, we point out that the use of elastic dislocation models of deformation (e.g., Okada, 1985) and, in turn, of induced Coulomb stress transfer on receiving preexisting faults (e.g., Toda et al, 2011) may be useful for more accurately predicting the probability of DF (e.g., Gürpinar et al, 2017;Livio et al, 2017), especially where the current models show higher residuals (e.g., at ca. 7-12 km in the hanging wall).…”

Section: Discussionmentioning

confidence: 87%

Conditional probability of distributed surface rupturing during normal-faulting earthquakes

Ferrario

2021

Solid Earth

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Abstract. Coseismic surface faulting is a significant source of hazard for critical plants and distributive infrastructure; it may occur either on the principal fault or as distributed rupture on nearby faults. Hazard assessment for distributed faulting is based on empirical relations which, in the case of normal faults, were derived almost 15 years ago using a dataset of US earthquakes. We collected additional case histories worldwide, for a total of 21 earthquakes, and calculated the conditional probability of distributed faulting as a function of distance from the principal fault. We found no clear dependency on the magnitude nor the time of occurrence of the earthquakes, but our data consistently show a higher probability of rupture when compared with the scaling relations currently adopted in engineering practice. We derive updated empirical regressions and show that the results are strongly conditioned by the averaging of earthquakes effectively generating distributed faulting at a given distance and those which did not generate faulting; thus, we introduce a more conservative scenario that can be included in a logic tree approach to consider the full spectrum of potential ruptures. Our results can be applied in the framework of probabilistic assessment of fault displacement hazard.

“…A quantitative correlation between observed DF, elastic dislocation models, and observed deformation fields, as captured by geodetic methods, can contribute to understanding how strain partitions. This, in turn, will lead to the definition of weighted factors to be implemented in PFDHA procedures, as recently suggested by Gürpinar et al ().…”

Section: Discussionmentioning

confidence: 99%

Characterizing the Distributed Faulting During the 30 October 2016, Central Italy Earthquake: A Reference for Fault Displacement Hazard Assessment

Ferrario

2018

Tectonics

Moderate to strong earthquakes (i.e., Mw >~6.0) commonly produce a complex network of ground ruptures, which are responsible for significant damage. Distributed faulting can affect wide areas (tenths of square kilometers), and expected displacement can be estimated through a probabilistic approach, considering distance from the primary fault and earthquake magnitude. Other factors may have a role in driving the occurrence of distributed faulting; nevertheless, they are not adequately addressed in the current modeling, due to a sensible lack of information. We study the 30 October 2016, Central Italy earthquake (Mw 6.5), to analyze the spatial pattern and geometric characteristics of distributed faulting. We found that distance from the primary structure, fault geometry, and lithology are key factors controlling the distributed faulting occurrence; the local structural setting (i.e., synthetic versus antithetic normal faults systems and relay zones) drives the spatial distribution of faults and the partitioning of the deformation. We also examine other four events occurred in the Italian Apennines since 1980, confirming that traditional models can underestimate the probability of distributed faulting. We suggest that a purely distance-based probabilistic approach should be integrated using additional parameters derived from earthquake deformation fields or considering the reactivation of preexisting faults.Plain Language Summary Surface faulting caused by moderate to strong earthquakes may occur along the major fault plane (primary fault) or along other structures in its proximity (distributed faulting). Distributed faulting can affect wide areas (tenths of square kilometers) and is responsible for significant damage. We assess the spatial pattern and geometric characteristics of distributed faulting of the 30 October 2016 Central Italy earthquake. We found that distance from the primary structure, fault geometry, and lithology are key factors controlling the distributed faulting occurrence. We also analyze four events that hit the Italian Apennines since 1980 and compare the results with the models currently adopted for estimating the possible amount of surface faulting caused by earthquakes. We found that current models, which are based on traditional field mapping methods, underestimate the probability of distributed faulting. We argue that the Central Italy 2016 event can act as a reference case study for fault displacement hazard assessment and that an increasing number of case histories will improve future mitigation strategies.PFDHA is the suggested approach for locating and designing critical or distributive infrastructures and utility lines, such as nuclear power plants (ANSI/ANS-2.30, 2015) and water pipelines. This method computes the probability of faulting occurrence as a function of distance from the primary fault and of earthquake FERRARIO AND LIVIO 1256