Insights into the assessment and interpretation of earthquake-induced liquefaction in sands under different degrees of saturation

Earthquake-induced liquefaction is a prominent and impactful natural hazard responsible for substantial economic losses worldwide. Hence, engineers and researchers are currently interested in developing methods and techniques to mitigate this destructive phenomenon. Reducing the degree of saturation...

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Bibliographic Details
Published in:Earth-science reviews 2024-11, Vol.258, p.104925, Article 104925
Main Authors: Molina-Gómez, Fausto, Viana da Fonseca, António, Ferreira, Cristiana, Caicedo, Bernardo
Format: Article
Language:English
Subjects:
engineering
engineers
exhibitions
financial economics
Gassy soils
Geohazard mitigation
geophysics
Liquefaction
methodology
Partial saturation
researchers
risk management
sand
Sands
sandy soils
soil liquefaction
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Summary:Earthquake-induced liquefaction is a prominent and impactful natural hazard responsible for substantial economic losses worldwide. Hence, engineers and researchers are currently interested in developing methods and techniques to mitigate this destructive phenomenon. Reducing the degree of saturation is a reliable method to improve the liquefaction resistance of sandy soils since it directly influences the pore pressure build-up during seismic action. This paper reviews the mechanisms and assessment of earthquake-induced liquefaction in sandy soils with various degrees of saturation, a crucial parameter for reducing the phenomenon triggering. In addition, it presents novel approaches that delve into interpreting cyclic behaviour with diverse degrees of saturation using stress-based and energy-based approaches. The experimental results compiled and discussed show that, effectively, reducing the degree of saturation holds promise as a viable strategy for enhancing soil liquefaction resistance and mitigating associated risks. Moreover, the interpretation of cyclic behaviour addressed in this paper offers valuable insights into the reliability of interpreting methods to quantify the liquefaction resistance under several degrees of saturation (that may be achieved by desaturation or induced partial saturation techniques), contributing to strategies for resilience against earthquake-induced damages. •Presentation of different methods to interpret the cyclic behaviour under different Sr•Database with results of cyclic element testing under several Sr in sands•Experimental evidence shows a reduction in Sr increases the cyclic strength.•Energy-based features to assess liquefaction resistance in sands with diverse Sr•Wave-based approach reliably describes the improvement in liquefaction resistance.
ISSN:0012-8252
DOI:10.1016/j.earscirev.2024.104925