Troy Singletary, Nima Iranmanesh and Carlos E. Colosqui
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引用次数: 0
摘要
这项研究提出了一种考虑到液体溶解力引起的流体动力阻力和动力学障碍影响的分析模型,用于预测纳米粒子在吸附表面上的平移扩散性。物理吸附在良好润湿表面的小纳米粒子可以通过热激活的粘滑运动保持显著的平面内流动性,这可以导致与自由空间布朗运动导致的体扩散性相当的表面扩散性。这项工作中的理论分析和分子动力学模拟表明,当 (i) Hamaker 常数小于由界面表面能和粒子尺寸规定的临界值,以及 (ii) 纳米粒子被吸附在分子尺寸远离壁的特定可转移分离处时,表面扩散性会增强。了解和控制这种现象对涉及分散在微米/纳米尺度约束下液体中的纳米材料的质量、电荷或能量传输的技术应用具有重要意义,例如基于膜的分离和超滤、表面电化学和催化以及界面自组装。
The surface diffusivity of nanoparticles physically adsorbed at a solid–liquid interface
This work proposes an analytical model considering the effects of hydrodynamic drag and kinetic barriers induced by liquid solvation forces to predict the translational diffusivity of a nanoparticle on an adsorbing surface. Small nanoparticles physically adsorbed to a well-wetted surface can retain significant in-plane mobility through thermally activated stick-slip motion, which can result in surface diffusivities comparable to the bulk diffusivity due to free-space Brownian motion. Theoretical analysis and molecular dynamics simulations in this work show that the surface diffusivity is enhanced when (i) the Hamaker constant is smaller than a critical value prescribed by the interfacial surface energy and particle dimensions, and (ii) the nanoparticle is adsorbed at specific metastable separations of molecular dimensions away from the wall. Understanding and controlling this phenomenon can have significant implications for technical applications involving mass, charge, or energy transport by nanomaterials dispersed in liquids under micro/nanoscale confinement, such as membrane-based separation and ultrafiltration, surface electrochemistry and catalysis, and interfacial self-assembly.
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