Abstract

When a colloidal suspension droplet evaporates from a solid surface, it leaves a characteristic deposit in the contact region. These deposits are common and important for many applications in printing, coating, or washing. By the use of superamphiphobic surfaces as a substrate, the contact area can be reduced so that evaporation is almost radially symmetric. While drying, the droplets maintain a nearly perfect spherical shape. Here, we exploit this phenomenon to fabricate supraparticles from bidisperse colloidal aqueous suspensions. The supraparticles have a core–shell morphology. The outer region is predominantly occupied by small colloids, forming a close-packed crystalline structure. Toward the center, the number of large colloids increases and they are packed amorphously. The extent of this stratification decreases with decreasing the evaporation rate. Complementary simulations indicate that evaporation leads to a local increase in density, which, in turn, exerts stronger inward forces on the larger colloids. A comparison between experiments and simulations suggest that hydrodynamic interactions between the suspended colloids reduce the extent of stratification. Our findings are relevant for the fabrication of supraparticles for applications in the fields of chromatography, catalysis, drug delivery, photonics, and a better understanding of spray-drying.

Highlights

  • When a suspension droplet evaporates from a solid surface, the previously dispersed colloids remain on the surfaces

  • We demonstrate that stratification of evaporating binary suspensions occurs for film-like geometry and for radial symmetric geometry

  • The distributions of small and large colloids in the supraparticles depend on the evaporation speed

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Summary

Introduction

When a suspension droplet evaporates from a solid surface, the previously dispersed colloids remain on the surfaces. The resulting radial flow of liquid enriches colloids at the periphery, where particles aggregate and form a ring- or doughnut-like structure.[11−17] As a result of line pinning at the periphery, drops often evaporate at a constant contact radius rather than at a constant contact angle. Another important case is the evaporation of free droplets, which occurs, for example, in spray drying (Figure 1d). Using super-liquid-repellent surfaces for the preparation of supraparticles may help to improve our understanding of spray drying

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