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A platform for research: civil engineering, architecture and urbanism
Quantifying Spatial Variability and Its Implications on the Risk of Liquefaction at a Recently Reclaimed Site
Sites gained on the sea through near-shore reclamation are vulnerable to liquefaction in the absence of soil improvement provisions. The need, extent, and degree of such provisions are function of the assessment of liquefaction susceptibility which depends on the in situ characteristics of the fill materials. Given the nature of the materials and the process of placement, spatial variability of the soil parameters is believed to be a significant source of uncertainty that will impact the estimated risk of liquefaction and the design of liquefaction-mitigation measures. In this paper, an array of 118 boreholes with standard penetration tests performed at 1.5 m depth intervals is utilized to characterize the spatial variability in the fill across a recently reclaimed site. Conditionally-simulated random fields were used to model the spatial variability of the N-values and the fines content at the site. The randomly simulated N-values and fines content were then used as input to an SPT-based liquefaction assessment framework to assess the risk of liquefaction of different zones within the site when subjected to different seismic loading scenarios. Results of the probabilistic analysis point to the importance of modeling spatial variability using realistic random fields that reflect the uncertainty in the soil properties of the site as portrayed in the site investigation data.
Quantifying Spatial Variability and Its Implications on the Risk of Liquefaction at a Recently Reclaimed Site
Sites gained on the sea through near-shore reclamation are vulnerable to liquefaction in the absence of soil improvement provisions. The need, extent, and degree of such provisions are function of the assessment of liquefaction susceptibility which depends on the in situ characteristics of the fill materials. Given the nature of the materials and the process of placement, spatial variability of the soil parameters is believed to be a significant source of uncertainty that will impact the estimated risk of liquefaction and the design of liquefaction-mitigation measures. In this paper, an array of 118 boreholes with standard penetration tests performed at 1.5 m depth intervals is utilized to characterize the spatial variability in the fill across a recently reclaimed site. Conditionally-simulated random fields were used to model the spatial variability of the N-values and the fines content at the site. The randomly simulated N-values and fines content were then used as input to an SPT-based liquefaction assessment framework to assess the risk of liquefaction of different zones within the site when subjected to different seismic loading scenarios. Results of the probabilistic analysis point to the importance of modeling spatial variability using realistic random fields that reflect the uncertainty in the soil properties of the site as portrayed in the site investigation data.
Quantifying Spatial Variability and Its Implications on the Risk of Liquefaction at a Recently Reclaimed Site
Kahiel, Ahmad (author) / Najjar, Shadi (author) / Sadek, Salah (author)
Eighth International Conference on Case Histories in Geotechnical Engineering ; 2019 ; Philadelphia, Pennsylvania
Geo-Congress 2019 ; 452-463
2019-03-21
Conference paper
Electronic Resource
English
| British Library Conference Proceedings | 2019
Liquefaction of Reclaimed Island in Kobe, Japan
| British Library Online Contents | 1996
Liquefaction of Reclaimed Island in Kobe, Japan
| Online Contents | 1996