Interparticle friction behaviors of kaolinite: Insights into macroscale friction from nanoscale

IF 5.3 2区地球科学 Q2 CHEMISTRY, PHYSICAL Applied Clay Science Pub Date : 2024-09-14 DOI:10.1016/j.clay.2024.107571

Li-Lan Zhang , Yuan-Yuan Zheng , Zhen-Yu Yin , Ali Zaoui

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Abstract

The friction behavior of widespread clay minerals is a major concern in many geo-engineering problems, such as the stability of soft soil foundations and the induction of seismic fault zones. The present work aimed to study the friction behaviors of kaolinite at the particle level using the molecular dynamics method. The effects of normal force (F_n), shear velocity (v), and interfacial water film on nanofriction were discussed. The “stick-slip” phenomenon and periodic evolution of friction forces (F_f) were observed in dry friction and became less pronounced with water lubrication. The dry F_f of kaolinite was found to be insensitive to F_n. However, wet F_f exhibited a linear increase with F_n and then transitioned to a non-linear relationship as slip displacement increases due to the continuous loss of water molecules from the interface during friction. Notably, at high loads (F_n ≥ 30 nN), the peak friction of wet kaolinite showed characteristics similar to dry friction. A velocity-strengthening behavior of kaolinite at high velocities was observed in both dry and wet conditions. The macroscale friction coefficients of kaolinite were predicted from nanofriction data and results showed good agreement with experimental values. This study lays the foundation for bridging micro- and macro-mechanical behaviors, suggesting a new pathway for acquiring precise macroscopic friction of minerals through cross-scale studies.

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高岭石的颗粒间摩擦行为：从纳米尺度洞察宏观摩擦力

广泛分布的粘土矿物的摩擦行为是许多地质工程问题（如软土地基的稳定性和地震断层带的诱导）中的一个主要关注点。本研究旨在利用分子动力学方法从颗粒层面研究高岭石的摩擦行为。讨论了法向力（Fn）、剪切速度（v）和界面水膜对纳米摩擦的影响。在干摩擦中观察到了 "粘滑 "现象和摩擦力（Ff）的周期性演变，而在水润滑时则变得不那么明显。研究发现，高岭石的干摩擦力对 Fn 不敏感。然而，湿摩擦力随 Fn 呈线性增长，然后随着滑移位移的增加而过渡到非线性关系，这是因为在摩擦过程中界面上的水分子不断流失。值得注意的是，在高载荷下（Fn ≥ 30 nN），湿高岭石的峰值摩擦力表现出与干摩擦力相似的特征。在干湿两种条件下，都观察到了高岭石在高速下的速度强化行为。根据纳米摩擦数据预测了高岭石的宏观摩擦系数，结果与实验值吻合。这项研究为连接微观和宏观力学行为奠定了基础，为通过跨尺度研究获得矿物的精确宏观摩擦力提供了新的途径。

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

Applied Clay Science 地学-矿物学

CiteScore

10.30

自引率

10.70%

发文量

289

审稿时长

39 days

期刊介绍： Applied Clay Science aims to be an international journal attracting high quality scientific papers on clays and clay minerals, including research papers, reviews, and technical notes. The journal covers typical subjects of Fundamental and Applied Clay Science such as: • Synthesis and purification • Structural, crystallographic and mineralogical properties of clays and clay minerals • Thermal properties of clays and clay minerals • Physico-chemical properties including i) surface and interface properties; ii) thermodynamic properties; iii) mechanical properties • Interaction with water, with polar and apolar molecules • Colloidal properties and rheology • Adsorption, Intercalation, Ionic exchange • Genesis and deposits of clay minerals • Geology and geochemistry of clays • Modification of clays and clay minerals properties by thermal and physical treatments • Modification by chemical treatments with organic and inorganic molecules(organoclays, pillared clays) • Modification by biological microorganisms. etc...