Abstract
Abstract. Liquefaction-induced hazards such as sand boils, ground cracks, settlement, and lateral spreading are responsible for considerable damage to engineering structures during major earthquakes. Presently, there is no effective empirical approach that can assess different liquefaction-induced hazards in one model. This is because of the uncertainties and complexity of the factors related to seismic liquefaction and liquefaction-induced hazards. In this study, Bayesian networks (BNs) are used to integrate multiple factors related to seismic liquefaction, sand boils, ground cracks, settlement, and lateral spreading into a model based on standard penetration test data. The constructed BN model can assess four different liquefaction-induced hazards together. In a case study, the BN method outperforms an artificial neural network and Ishihara and Yoshimine's simplified method in terms of accuracy, Brier score, recall, precision, and area under the curve (AUC) of the receiver operating characteristic (ROC). This demonstrates that the BN method is a good alternative tool for the risk assessment of liquefaction-induced hazards. Furthermore, the performance of the BN model in estimating liquefaction-induced hazards in Japan's 2011 Tōhoku earthquake confirms its correctness and reliability compared with the liquefaction potential index approach. The proposed BN model can also predict whether the soil becomes liquefied after an earthquake and can deduce the chain reaction process of liquefaction-induced hazards and perform backward reasoning. The assessment results from the proposed model provide informative guidelines for decision-makers to detect the damage state of a field following liquefaction.
Highlights
The prediction of liquefaction potential (LP) and assessment of liquefaction-induced hazards are two significant and closely related problems
Existing empirical methods for estimating hazards induced by seismic liquefaction can only assess a single type of ground failure and cannot predict ground cracks and sand boils (e.g. the empirical formulas constructed by Youd and Perkins, 1987; Youd et al, 2002, the multivariate adaptive regression splines (MARS) model constructed by Goh and Zhang, 2014, for estimating lateral spreading, and the different simplified procedures for estimating the settlement proposed by Ishihara and Yoshimine, 1992; Zhang et al, 2002; Wu and Seed, 2004; and Juang et al, 2013)
Given the uncertainty and complexity of liquefactioninduced hazards, this paper described a generic Bayesian networks (BNs) model for estimating the risk of different hazards induced by seismic liquefaction based on historical disaster data
Summary
The prediction of liquefaction potential (LP) and assessment of liquefaction-induced hazards are two significant and closely related problems. The prediction of LP in foundation soils is only the first step in assessing liquefaction hazards This has been well studied in recent decades, such as by simplified methods (Seed and Idriss, 1971, 1982; Starks and Olsen, 1995; Stokoe and Nazarian, 1985) based on standard penetration test (SPT), cone penetration test (CPT), and shear wave velocity measurements, laboratory testing, numerical methods, and empirical liquefaction models (Goh, 1994; Zhang and Goh, 2013, 2016; Pal, 2006; Toprak et al, 1999; Zhang et al, 2015) based on historical data. Recent advances in physical model experiments and the computational modelling of liquefaction-induced ground deforma-
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