Liquefaction susceptibility of clayey sands under saturated and partially saturated conditions

IF 4.2 1区工程技术 Q1 ENGINEERING, GEOLOGICAL

Geotechnique Pub Date : 2023-11-13 DOI:10.1680/jgeot.23.00100

Pedram Fardad Amini, Jun Yang

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引用次数: 0

Abstract

Experiences from previous earthquake events indicated that sands containing non-plastic (silt) or plastic (clay) fines are susceptible to liquefaction. These experiences underline the need for improving the fundamental understanding of the seismic behaviour of silty and clayey sands and for developing appropriate methods to evaluate their liquefaction potential. This paper presents an attempt to elucidate the integrated effects of fines (non-plastic silt and plastic clay) inclusion and degree of saturation on the cyclic behaviour and liquefaction resistance of sands based on systematic experiments. One of the notable findings of the study is that, apart from the familiar mode of cyclic mobility, clayey sand can also undergo flow-type failure under either fully or partially saturated conditions. The unified correlation between the cyclic resistance ratio (CRR) and the state parameter (ψ), established earlier for clean and silty sand in the framework of critical state soil mechanics (CSSM), is found to work for clayey sand as well. Furthermore, it is shown that the impact of saturation on the cyclic strength of clean and clayey sands can be reasonably characterised using the compression wave velocity normalized by the shear wave velocity.

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粘土砂在饱和和部分饱和条件下的液化敏感性

以往地震事件的经验表明，含有非塑性(淤泥)或塑性(粘土)细粒的砂容易液化。这些经验强调有必要提高对粉质和粘土砂的地震行为的基本认识，并制定适当的方法来评价其液化潜力。本文在系统试验的基础上，试图阐明细粒(非塑性粉砂和塑性粘土)包裹体和饱和度对砂土循环特性和抗液化性能的综合影响。该研究的一个显著发现是，除了常见的循环迁移模式外，粘土砂在完全或部分饱和条件下也可能发生流动型破坏。在临界状态土力学(CSSM)框架下，较早建立的洁净砂和粉砂循环阻力比(CRR)与状态参数(ψ)之间的统一关联，同样适用于粘性砂。此外，饱和度对洁净砂和粘性砂循环强度的影响可以用剪切波速归一化的压缩波速来合理表征。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Geotechnique 工程技术-地球科学综合

CiteScore

9.80

自引率

10.30%

发文量

168

审稿时长

7 months

期刊介绍： Established in 1948, Géotechnique is the world''s premier geotechnics journal, publishing research of the highest quality on all aspects of geotechnical engineering. Géotechnique provides access to rigorously refereed, current, innovative and authoritative research and practical papers, across the fields of soil and rock mechanics, engineering geology and environmental geotechnics.