单轴压缩和单向剪切作用下钠蒙脱土的分子动力学模拟

IF 1.1 4区地球科学 Q4 CHEMISTRY, PHYSICAL

Clay Minerals Pub Date : 2022-09-01 DOI:10.1180/clm.2022.42

Ran Yuan, Wen-Ming Wang, Yi He, Yong Fang, Xi-Long Huang

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引用次数: 1

摘要

摘要本文建立了单轴压缩和单向剪切作用下钠蒙脱土的系统分子动力学模型。使用Build Crystal模块建立了单细胞na -蒙脱土结构的初始3D模型。空间组为C2/m，采用COMPASS力场。对钠蒙脱土进行水化分析以验证模拟过程，其中吸收的水分子数量随各种晶格参数而变化。对钠蒙脱土结构施加了一系列单轴压缩应力σzz和单向剪切应力τxy值。结果表明，晶格参数和水化程度对钠蒙脱土的应力-应变关系有显著影响。最终应变随晶格参数的增大而增大，但随水分子数的减小而减小。饱和钠蒙脱土在单轴压缩和单向剪切作用下，水分子越多，粘土矿物越坚硬。

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Molecular dynamics modelling of Na-montmorillonite subjected to uniaxial compression and unidirectional shearing

Abstract This paper presents systematic molecular dynamics modelling of Na-montmorillonite subjected to uniaxial compression and unidirectional shearing. An initial 3D model of a single-cell Na-montmorillonite structure is established using the Build Crystal module. The space group is C2/m, and COMPASS force fields are applied. Hydration analysis of Na-montmorillonite has been performed to validate the simulation procedures, where the number of absorbed water molecules varied with respect to the various lattice parameters. A series of uniaxial compression stress σzz and unidirectional shear stress τxy values are applied to the Na-montmorillonite structure. It is shown that the lattice parameter and hydration degree exhibit significant influence on the stress–strain relationship of Na-montmorillonite. The ultimate strain increases with increases in the lattice parameter but decreases in the number of water molecules. For saturated Na-montmorillonite, more water molecules result in a stiffer clay mineral under uniaxial compression and unidirectional shearing.

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来源期刊

Clay Minerals 地学-矿物学

CiteScore

3.00

自引率

20.00%

发文量

审稿时长

6 months

期刊介绍： Clay Minerals is an international journal of mineral sciences, published four times a year, including research papers about clays, clay minerals and related materials, natural or synthetic. The journal includes papers on Earth processes soil science, geology/mineralogy, chemistry/material science, colloid/surface science, applied science and technology and health/ environment topics. The journal has an international editorial board with members from fifteen countries.