A Review of Sand Aging: Mechanisms and Impacts

Miguel Castilla-Barbosa; Manuel Ocampo-Terreros; Orlando Rincón-Arango

doi:10.1007/s10706-024-02923-0

A Review of Sand Aging: Mechanisms and Impacts

Miguel Castilla-Barbosa, Manuel Ocampo-Terreros, Orlando Rincón-Arango

Department of Civil Engineering

Research output: Contribution to journal › Review article › peer-review

1 Scopus citations

Abstract

Sand aging, defined by time-dependent increases in stiffness and strength over periods ranging from days to months, poses significant challenges in geotechnical engineering and soil science. Despite its relevant implications, the mechanisms driving sand aging remain understood. This review systematically examines sand aging, emphasizing the classification of chemical and mechanical processes involved. Key advancements in chemical aging understanding, particularly the influence of surface chemistry and electrokinetic forces, are discussed. Additionally, the review underscores the critical role of micromechanical modeling, especially discrete element methods, in elucidating particle interactions and aging phenomena. The review also identifies essential directions for future research, notably incorporating particle shape and surface texture into aging models. Hence, this comprehensive resource aims to enhance the understanding of sand aging.

Original language	English
Pages (from-to)	6727-6755
Number of pages	29
Journal	Geotechnical and Geological Engineering
Volume	42
Issue number	8
DOIs	https://doi.org/10.1007/s10706-024-02923-0
State	Published - 21 Sep 2024

Keywords

Electrochemistry
Electrokinetics
Geochemistry
Sand aging
Time dependence

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10.1007/s10706-024-02923-0

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title = "A Review of Sand Aging: Mechanisms and Impacts",

abstract = "Sand aging, defined by time-dependent increases in stiffness and strength over periods ranging from days to months, poses significant challenges in geotechnical engineering and soil science. Despite its relevant implications, the mechanisms driving sand aging remain understood. This review systematically examines sand aging, emphasizing the classification of chemical and mechanical processes involved. Key advancements in chemical aging understanding, particularly the influence of surface chemistry and electrokinetic forces, are discussed. Additionally, the review underscores the critical role of micromechanical modeling, especially discrete element methods, in elucidating particle interactions and aging phenomena. The review also identifies essential directions for future research, notably incorporating particle shape and surface texture into aging models. Hence, this comprehensive resource aims to enhance the understanding of sand aging.",

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AU - Castilla-Barbosa, Miguel

AU - Ocampo-Terreros, Manuel

AU - Rincón-Arango, Orlando

N1 - Publisher Copyright: © The Author(s) 2024.

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Y1 - 2024/9/21

N2 - Sand aging, defined by time-dependent increases in stiffness and strength over periods ranging from days to months, poses significant challenges in geotechnical engineering and soil science. Despite its relevant implications, the mechanisms driving sand aging remain understood. This review systematically examines sand aging, emphasizing the classification of chemical and mechanical processes involved. Key advancements in chemical aging understanding, particularly the influence of surface chemistry and electrokinetic forces, are discussed. Additionally, the review underscores the critical role of micromechanical modeling, especially discrete element methods, in elucidating particle interactions and aging phenomena. The review also identifies essential directions for future research, notably incorporating particle shape and surface texture into aging models. Hence, this comprehensive resource aims to enhance the understanding of sand aging.

AB - Sand aging, defined by time-dependent increases in stiffness and strength over periods ranging from days to months, poses significant challenges in geotechnical engineering and soil science. Despite its relevant implications, the mechanisms driving sand aging remain understood. This review systematically examines sand aging, emphasizing the classification of chemical and mechanical processes involved. Key advancements in chemical aging understanding, particularly the influence of surface chemistry and electrokinetic forces, are discussed. Additionally, the review underscores the critical role of micromechanical modeling, especially discrete element methods, in elucidating particle interactions and aging phenomena. The review also identifies essential directions for future research, notably incorporating particle shape and surface texture into aging models. Hence, this comprehensive resource aims to enhance the understanding of sand aging.

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KW - Electrokinetics

KW - Geochemistry

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KW - Time dependence

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A Review of Sand Aging: Mechanisms and Impacts

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