2012
DOI: 10.1039/c2sm26574e
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Modelling the formation of structured deposits at receding contact lines of evaporating solutions and suspensions

Abstract: When a film of a liquid suspension of nanoparticles or a polymer solution is deposited on a surface, it may dewet from the surface and as the solvent evaporates the solute particles/polymer can be deposited on the surface in regular line patterns. In this paper we explore a hydrodynamic model for the process that is based on a long-wave approximation that predicts the deposition of irregular and regular line patterns. This is due to a self-organised pinning-depinning cycle that resembles a stick-slip motion of… Show more

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Cited by 64 publications
(107 citation statements)
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References 105 publications
(285 reference statements)
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“…Even though a number of simplifying assumptions are made (in order to isolate the influences of concentration-dependent viscosity and diffusivity), dramatic changes in the dynamics are observed. In practice, many other phenomena may come into play, including partial wetting, more complex rheology (Jeong et al 2010;Hewitt & Balmforth 2013), particle adsorption and desorption at the liquid-air interface and in the contact-line region, evaporation (Fraštia, Archer & Thiele 2012), the effects of structural disjoining pressure (Trokhymchuk et al 2001;Matar et al 2007;Wasan et al 2011;Kondiparty et al 2012;Liu et al 2012), and three-dimensional dynamics. Nevertheless, by focusing on the important and physically relevant limiting case of perfectly wetting systems, the present work provides a foundation and motivation for examining these issues.…”
Section: Discussionmentioning
confidence: 99%
“…Even though a number of simplifying assumptions are made (in order to isolate the influences of concentration-dependent viscosity and diffusivity), dramatic changes in the dynamics are observed. In practice, many other phenomena may come into play, including partial wetting, more complex rheology (Jeong et al 2010;Hewitt & Balmforth 2013), particle adsorption and desorption at the liquid-air interface and in the contact-line region, evaporation (Fraštia, Archer & Thiele 2012), the effects of structural disjoining pressure (Trokhymchuk et al 2001;Matar et al 2007;Wasan et al 2011;Kondiparty et al 2012;Liu et al 2012), and three-dimensional dynamics. Nevertheless, by focusing on the important and physically relevant limiting case of perfectly wetting systems, the present work provides a foundation and motivation for examining these issues.…”
Section: Discussionmentioning
confidence: 99%
“…Note, that the understanding of the bifurcation scenario of deposition processes is not only important for the dip-coating process at hand and the Langmuir-Blodgett transfer [31,32]. It is also relevant for line deposition from solutions and suspensions with volatile solvent where other instability mechanisms dominate, see, e.g., the case of evaporative dewetting [77,78]. It was pointed out in [77] and more extensively discussed in [32] that the onset of periodic deposition at the lower limiting velocity may be considered a depinning transition as beyond this critical velocity part of the steady meniscus profile depins and is dragged away from the bath as liquid ridge.…”
Section: Discussionmentioning
confidence: 99%
“…These asymptotic forms, truncated after a few terms, are used frequently throughout the literature (independently or as combinations of the two forms 1,25,43,44 ) even though they are only strictly valid for thick liquid films and cannot describe the binding potential as h → 0. To describe the small h behaviour, the full form of g(h) is required.…”
Section: The Binding Potentialmentioning
confidence: 99%