A study of stability of the seafloor foundation on a gently sloping continental shelf |
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| Authors: | Liang Yuanbo Lu Bo Huang Shaojian Li Tinghuan Yang Weiguang Wen Yaolin |
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| Institution: | 1. South China Sea Institute of Oceanology , Academia Sinica , 164 West Xingang Road, Guangzhou, 510301, P.R. China;2. Guangzhou Marine Geological Survey , MGMR , P.O. Box 950, Guangzhou, 510075, P.R. China;3. South China University of Technology , Shipai, Guangzhou, 510641, P.R. China |
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| Abstract: | Abstract The possibility of seafloor failure under external loadings on a gently sloping continental shelf is controlled, to a large extent, by the geotechnical characters of subbottom sediments (e.g., shear strength, compressibility, and liquefaction potential) and structural factors (e.g., sedimentary stratification). By means of undis‐turbing coring, in‐situ acoustic measurement, and subbottom profiling, the authors conducted an investigation into the seafloor instabilities and possibilities of sediment slope failure within the continental shelf off the Pearl River mouth, which is one of the most important areas for offshore development in the northern South China Sea. Based on in‐situ and laboratory measurements and tests for sediment physical properties, static and dynamic behavior, and acoustic characteristics, the analyses indicate: (1) subbottom sediments that originated from terrigenous clay during the Pleistocene are compact and overconsolidated, and the mean sound velocity in such sediments is relatively high; (2) the maximum vertical bearing capacity of subbottom sediments is efficiently conservative on the safe side for dead loads of light structures, and the trench walls are stable enough while trenching to a depth of about 2 m below the seafloor under still water; and (3) it is quite improbable that the subbottom sediments liquefy under earthquake (M ≤ 6) or storm wave loading. |
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| Keywords: | seafloor stability engineering characteristics soil mechanics sound velocity subbottom sediment earthquake shaking wave loading liquefaction potential South China Sea |
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