pH-Switchable Stratification of Colloidal Coatings: Surfaces “On Demand”

Martín-Fabiani, Ignacio; Fortini, Andrea; Haye, Jennifer Lesage de la; Koh, Ming Liang; Taylor, Spencer E.; Bourgeat‐Lami, Élodie; Lansalot, Muriel; D’Agosto, Franck; Sear, Richard P.; Keddie, Joseph L.

doi:10.1021/acsami.6b12015

Cited by 44 publications

(68 citation statements)

References 42 publications

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“…While there are currently no experiments available for stratification in polymer mixtures, colloid mixtures have been shown to stratify in experiments. [12][13][14] The extent of colloid stratification in the experiments appears weaker than predicted by models lacking hydrodynamic interactions, 12 consistent with our analysis. Larger chemical potential gradients on the larger component would be required to increase the stratification, which could be induced by, for example, larger size ratios or additional cross-interactions between the components.…”

Section: Discussionsupporting

confidence: 88%

“…17 The stratification was more pronounced for larger size ratios and faster drying speeds, although it was found to persist even at moderate drying rates. 13,15,17 Stratification has been modeled theoretically as a diffusion process 7,18 qualitatively predicted a maximum in the number of large colloids on top of the film when Pe 1 < 1 and Pe 2 > 1 (here 1 is the smaller colloid and 2 is the larger colloid). 20 For computational and theoretical convenience, many previous studies have employed a free-draining approximation for hydrodynamic interactions on the colloids or polymers, incorporating the Stokes drag on each particle but neglecting other interactions.…”

Section: Introductionmentioning

confidence: 99%

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Influence of hydrodynamic interactions on stratification in drying mixtures

Statt

Howard

Panagiotopoulos

2018

The Journal of Chemical Physics

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Nonequilibrium molecular dynamics simulations are used to investigate the influence of hydrodynamic interactions on vertical segregation (stratification) in drying mixtures of long and short polymer chains. In agreement with previous computer simulations and theoretical modeling, the short polymers stratify above the long polymers at the top of the drying film when hydrodynamic interactions between polymers are neglected. However, no stratification occurs under the same drying conditions when hydrodynamic interactions are incorporated through an explicit solvent model. Our analysis demonstrates that models lacking hydrodynamic interactions do not faithfully represent stratification in drying mixtures, in agreement with the recent analysis of an idealized model for diffusiophoresis. Hydrodynamic interactions must be incorporated into such models for drying mixtures in future.

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Section: Discussionsupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Influence of hydrodynamic interactions on stratification in drying mixtures

Statt

Howard

Panagiotopoulos

2018

The Journal of Chemical Physics

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“…Martín-Fabiani et al studied a system with the smaller particles coated with hydrophilic shells and explored the effect of changing the pH of the initial dispersion. [19] In a dispersion with low pH, α is large enough to lead to "small-ontop" stratification. When the pH is raised, α is reduced as the hydrophilic shells swell substantially, and stratification is suppressed.…”

Section: Introductionmentioning

confidence: 99%

Control of Stratification in Drying Particle Suspensions via Temperature Gradients

2019

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A potential strategy for controlling stratification in a drying suspension of bidisperse particles is studied using molecular dynamics simulations. When the suspension is maintained at a constant temperature during fast drying, it can exhibit "small-on-top" stratification with an accumulation (depletion) of smaller (larger) particles in the top region of the drying film, consistent with the prediction of current theories based on diffusiophoresis. However, when only the region near the substrate is thermalized at a constant temperature, a negative temperature gradient develops in the suspension because of evaporative cooling at the liquid-vapor interface. Since the associated thermophoresis is stronger for larger nanoparticles, a higher fraction of larger nanoparticles migrate to the top of the drying film at fast evaporation rates. As a result, stratification is converted to "large-on-top". Very strong "small-on-top" stratification can be produced with a positive thermal gradient in the drying suspension. Here we explore a way to produce a positive thermal gradient by thermalizing the vapor at a temperature higher than that of the solvent. Possible experimental approaches to realize various thermal gradients in a suspension undergoing solvent evaporation, and thus to produce different stratification states in the drying film, are suggested. arXiv:1810.01384v2 [cond-mat.soft]

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Section: Adv Mater 2017 29 1703769mentioning

confidence: 99%

“…Martin-Fabiani et al [46] synthesized nanoparticles with a hairy shell composed of hydrophilic poly(methyl acrylate) (PMAA) chains. By increasing the pH, the polymer chains change from a collapse state to an extended state, effectively increasing the particle size.…”

Section: Adv Mater 2017 29 1703769mentioning

confidence: 99%

Structure Formation in Soft‐Matter Solutions Induced by Solvent Evaporation

et al. 2017

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etc., and the interplay between different processes determines the final structure of the dried materials.Here, we report recent advances of selfassembled structures induced by uniform evaporation, examples including drying in a thin-film geometry or evaporating a spherical droplet on a superhydrophobic surface. [4] In these situations, the structure formation takes place in the direction of the evaporation. This excludes the case where lateral flow is induced by nonuniform drying. The lateral flow is important in explaining the coffee-ring effect, where excellent reviews exist in literature. [5,6] After introducing the general procedure in experiments, we explain the physical mechanisms responsible for the structure formation in solvent evaporation. We then discuss recent advances based on single-and binarycomponent solutions, with a special emphasis on the theoretical approaches. Drying of Single-Component SolutionsA general experiment starts with spin-coating a thin-film solution on a substrate, then the sample is left to dry. In the first step, it is important that the spin-cast film is uniform. [7,8] In the second step, the evaporation flux, i.e., the mass removed from the liquid phase to the vapor phase in unit time from unit surface area needs to be controlled precisely. Even for the pure solvent evaporation, the process is complex and involves the diffusion of solvent molecules in both the liquid and vapor phases, and external flow in the vapor phase to prevent saturation. The evaporation flux can be computed using the Hertz-Knudsen equation that is based on the thermodynamics variables [9][10][11] or solving the diffusion equation in the vapor phase using suitable boundary conditions. [12][13][14] The solvent evaporation drives the free surface to recede toward the substrate, resulting in an accumulation of the solutes at the surface. Two competing processes determine the spatial distribution of the solutes. One is the Brownian motion, which is characterized by the diffusion constant D of the solutes. The other is the evaporation, characterized by the rate v ev at which the free surface recedes. Two timescales are related to these two processes: the diffusion time τ D =  2 /D, where  is a characteristic length and the evaporation time τ ev = /v ev . To quantify the relative importance between the diffusion and the evaporation, one can define a dimensionless number called film formation Peclet number: [15]

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pH-Switchable Stratification of Colloidal Coatings: Surfaces “On Demand”

Cited by 44 publications

References 42 publications

Influence of hydrodynamic interactions on stratification in drying mixtures

Influence of hydrodynamic interactions on stratification in drying mixtures

Control of Stratification in Drying Particle Suspensions via Temperature Gradients

Structure Formation in Soft‐Matter Solutions Induced by Solvent Evaporation

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