Arrested coalescence of viscoelastic droplets: Ellipsoid shape effects and restructuring

TL;DR

This study investigates how ellipsoid-shaped viscoelastic droplets undergo arrested coalescence, revealing how shape, elasticity, and energy constraints influence their final configurations and stability.

Contribution

It introduces a micromanipulation method to analyze the arrested coalescence of ellipsoidal viscoelastic droplets and maps their possible stable configurations considering shape and elasticity effects.

Findings

Droplet shape and elasticity significantly influence restructuring behavior.

Higher aspect ratios lead to greater restructuring and stability.

Deviations from energy calculations reveal the role of constraint forces.

Abstract

The stable configurations formed by two viscoelastic, ellipsoid-shaped droplets during their arrested coalescence has been investigated using micromanipulation experiments. Ellipsoidal droplets are produced by millifluidic emulsification of petrolatum into a yield stress fluid that preserves their elongated shape. The liquid meniscus between droplets can transmit stress and instigate movement of the droplets, from their initial relative position, in order to minimize doublet surface energy. The action of the liquid meniscus causes the ellipsoidal droplets to undergo rolling and restructuring events because of their unique ellipsoid shape and associated variation in surface curvature. The final configuration of the droplets is shown to be controlled by the balance between interfacial Laplace pressure and internal elasticity, as well as a constraint force that resists complete minimization of surface energy. Geometric and surface energy calculations are used to map the possible and most likely configurations of the droplet pairs. Experimental deviations from the calculations indicate the magnitude and potential origin of the constraint force resisting full equilibration. Droplet aspect ratio and elasticity are both shown to influence the degree of restructuring and stability of the droplets at energy extrema. Higher aspect ratios drive greater restructuring and better agreement with final doublet configurations predicted by energy minimization. Lower elasticity droplets undergo secondary deformations at high aspect ratios, further broadening the space of possible morphologies.