Stratification in drying films: Diffusiophoresis driven by nanoparticles and their counterions

IF 1.4 4区 数学 Q2 MATHEMATICS, APPLIED
Clare R. Rees-Zimmerman, Alexander F Routh
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引用次数: 0

Abstract

Recent experimental work has highlighted that electrolyte-driven diffusiophoresis is likely to be the most significant phoretic motion in a mixture of silica nanoparticles and relatively large latex particles, which are commonly used in coatings. In this present work, this diffusiophoretic effect, powered by gradients in the nanoparticles and their stabilising cations, is modelled in drying films. A continuum hydrodynamic model is derived, and the resulting partial differential equations solved numerically. An asymptotic solution is found for high evaporation rate. It is found that the final film structure is governed by the relative magnitudes of the diffusive and diffusiophoretic terms. Two methods are discovered to control the resulting stratification: (i) setting the surface charge on the particles, and (ii) setting the background salt concentration. Either of these can be used to select either small- or large-on-top stratification or a homogenous film. The diffusiophoretic term promotes small-on-top stratification, and so may account for experimental observations of accumulated small particles at the top surface of dried films.
干燥薄膜的分层:由纳米粒子及其反离子驱动的扩散电泳
最近的实验工作表明,电解质驱动的扩散泳动很可能是二氧化硅纳米粒子和相对较大的乳胶粒子混合物(常用于涂料)中最重要的幻影运动。在本研究中,这种由纳米粒子及其稳定阳离子的梯度驱动的扩散蠕动效应被模拟在干燥薄膜中。推导出了一个连续流体力学模型,并对由此产生的偏微分方程进行了数值求解。找到了高蒸发率下的渐近解。研究发现,最终的薄膜结构受扩散项和扩散蠕动项相对大小的制约。发现了两种控制分层结果的方法:(i) 设置颗粒表面电荷;(ii) 设置背景盐浓度。这两种方法中的任何一种都可用于选择顶部小分层或顶部大分层或均质膜。扩散项会促进顶部小颗粒分层,因此可以解释实验观察到的干燥薄膜顶部表面积聚小颗粒的原因。
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
CiteScore
2.30
自引率
8.30%
发文量
32
审稿时长
24 months
期刊介绍: The IMA Journal of Applied Mathematics is a direct successor of the Journal of the Institute of Mathematics and its Applications which was started in 1965. It is an interdisciplinary journal that publishes research on mathematics arising in the physical sciences and engineering as well as suitable articles in the life sciences, social sciences, and finance. Submissions should address interesting and challenging mathematical problems arising in applications. A good balance between the development of the application(s) and the analysis is expected. Papers that either use established methods to address solved problems or that present analysis in the absence of applications will not be considered. The journal welcomes submissions in many research areas. Examples are: continuum mechanics materials science and elasticity, including boundary layer theory, combustion, complex flows and soft matter, electrohydrodynamics and magnetohydrodynamics, geophysical flows, granular flows, interfacial and free surface flows, vortex dynamics; elasticity theory; linear and nonlinear wave propagation, nonlinear optics and photonics; inverse problems; applied dynamical systems and nonlinear systems; mathematical physics; stochastic differential equations and stochastic dynamics; network science; industrial applications.
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