Abstract

Ground-motion models (GMMs) are often used to predict the random distribution of Spectral accelerations ( $$\mathrm{SAs}$$ ) at a site due to a nearby earthquake. In probabilistic seismic hazard and risk assessment, large earthquakes occurring close to a site are considered as critical scenarios. GMMs are expected to predict realistic $$\mathrm{SAs}$$ with low within-model uncertainty ( $${\upsigma }_{\upmu }$$ ) for such rare scenarios. However, the datasets used to regress GMMs are usually deficient of data from critical scenarios. The (Kotha et al., A Regionally Adaptable Ground-Motion Model for Shallow Crustal Earthquakes in Europe Bulletin of Earthquake Engineering 18:4091–4125, 2020) GMM developed from the Engineering strong motion (ESM) dataset was found to predict decreasing short-period $$\mathrm{SAs}$$ with increasing $${M}_{W}\ge {\mathrm{M}}_{\mathrm{h}}=6.2$$ , and with large $${\upsigma }_{\upmu }$$ at near-source distances $$\le 30\mathrm{km}$$ . In this study, we updated the parametrisation of the GMM based on analyses of ESM and the Near source strong motion (NESS) datasets. With $${\mathrm{M}}_{\mathrm{h}}=5.7$$ , we could rectify the $${M}_{W}$$ scaling issue, while also reducing $${\upsigma }_{\upmu }$$ at $${M}_{W}\ge {\mathrm{M}}_{\mathrm{h}}$$ . We then evaluated the GMM against NESS data, and found that the $$\mathrm{SAs}$$ from a few large, thrust-faulting events in California, New Zealand, Japan, and Mexico are significantly higher than GMM median predictions. However, recordings from these events were mostly made on soft-soil geology, and contain anisotropic pulse-like effects. A more thorough non-ergodic treatment of NESS was not possible because most sites sampled unique events in very diverse tectonic environments. We provide an updated set of GMM coefficients, $${\upsigma }_{\upmu }$$ , and heteroscedastic variance models; while also cautioning against its application for $${M}_{W}\le 4$$ in low-moderate seismicity regions without evaluating the homogeneity of $${M}_{W}$$ estimates between pan-European ESM and regional datasets.

Highlights

  • A ground-motion observation at a site from an earthquake is often reported as the peak acceleration response of a 5% damped Single-degree-of-freedom (SDOF) oscillator with fundamental period T when excited by the recorded accelerogram at the site

  • We first discussed the adequacy of various fixed-effects in the Ground-Motion Models (GMMs) in capturing the primary physical phenomenon controlling the seismic ground-motion observations

  • An outstanding issue with the GMM was the oversaturation of short-period SAs with increasing magnitude at near-source distances

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Summary

Introduction

A ground-motion observation at a site from an earthquake is often reported as the peak acceleration response of a 5% damped Single-degree-of-freedom (SDOF) oscillator with fundamental period T when excited by the recorded accelerogram at the site. The top-left panel of Fig. 1, showing the distribution of recordings in (MW vsRJB) ranges of the two datasets, clearly shows that NESS complements ESM with several recordings from hazard critical scenarios ( MW ≥ 5.5&RJB ≤ 30 km )— albeit from global earthquakes originating in very diverse tectonic environments, and recorded by stations in very particular geological settings. This plot shows that 30% of the NESS recordings are characterised by pulse-like characteristics, either due to geological or finite-fault effects. We discuss the re-parametrization of the Kotha et al (2020) GMM, consequent impact on its within-model (epistemic) and aleatory uncertainties, its limitation in capturing the complex near-source finite-fault phenomenon, and the apparent (or actual) global diversity of MW ≥ 5.5 shallow crustal earthquakes

Functional form
Results and discussion
Fixed‐effects
Random‐effects and residuals
Evaluation with ness dataset
Dataset
Heteroscedasticity
10 Conclusions

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