Analysis of Profile and Morphology of Colloidal Deposits obtained from Evaporating Sessile Droplets
Laxman K. Malla, Rajneesh Bhardwaj, Adrian Neild

TL;DR
This study experimentally analyzes the morphology and profile of colloidal deposits from evaporating sessile droplets, revealing how particle size and concentration influence deposit types, with implications for self-assembly design.
Contribution
It provides a detailed classification of deposit morphologies based on particle size and concentration, and validates a power-law scaling with a theoretical model.
Findings
Ring profile resembles a partial torus.
Cracks occur at small particle size and high concentration.
Scaling laws match continuum model.
Abstract
We experimentally investigate the profile and morphology of the ring-like deposits obtained after evaporation of a sessile water droplet containing polystyrene colloidal particles on a hydrophilic glass substrate. In particular, the coupled effect of particle size and concentration are studied. The deposits were qualitatively visualized under an optical microscope and profile of the ring was measured by an optical profilometer. The profile of the ring resembles a partial torus-like shape for all cases of particles size and concentration. The cracks on the surface of the ring were found to occur only at smaller particle size and larger concentration. We plot a regime map to classify three deposit types - discontinuous monolayer ring, continuous monolayer ring, and multiple layers ring - on particles concentration - particle size plane. Our data shows a possible existence of a critical…
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Taxonomy
TopicsNanomaterials and Printing Technologies · Innovative Microfluidic and Catalytic Techniques Innovation · Fluid Dynamics and Thin Films
