Microscale investigation of binary droplet coalescence using a microfluidic hydrodynamic trap

TL;DR

This study uses a microfluidic hydrodynamic trap to investigate how various parameters like surfactant concentration and droplet size influence the coalescence process of micrometer-sized droplets, revealing critical conditions and surfactant effects.

Contribution

It introduces a novel microfluidic hydrodynamic trap method for detailed, controlled study of binary droplet coalescence at microscale, highlighting surfactant effects and critical coalescence conditions.

Findings

Higher surfactant concentrations increase film drainage time.

Larger droplets and higher confinement lead to longer drainage times.

Surfactant gradients can induce coalescence after initial flocculation.

Abstract

Coalescence of micrometer-scale droplets is impacted by several parameters, including droplet size, viscosities of the two phases, droplet velocity and angle of approach, as well as interfacial tension and surfactant coverage. The dynamics and thinning of films between coalescing droplets can be particularly complex in the presence of surfactants, due to the generation of Marangoni stresses and reduced film mobility. In this work, a microfluidic hydrodynamic Stokes trap is used to gently steer and trap surfactant-laden micrometer-sized droplets at the center of a cross-slot. Incoming droplets are made to coalesce with the trapped droplet, yielding measurements of the film drainage time. Water droplets are formed upstream using a microfluidic T-junction, in heavy and light mineral oils and stabilized using SPAN 80, an oil-soluble surfactant. Film drainage times are measured as a function of continuous phase viscosity, incoming droplet speed, trapped droplet size, and surfactant concentrations above and below the critical micelle concentration (CMC). As expected, systems with higher surfactant concentrations, higher continuous phase viscosity, and slower droplet speed exhibit longer film drainage times. Perhaps more surprisingly, larger droplets and high confinement also result in longer film drainage times. The results are used here to determine critical conditions for coalescence, including both an upper and a lower critical Capillary number. Moreover, it is shown that induced surfactant concentration gradient effects enable coalescence events after the droplets had originally flocculated, at surfactant concentrations above the CMC. The microfluidic hydrodynamic trap provides new insights into the role of surfactants in film drainage and opens avenues for controlled coalescence studies at micrometer length scales and millisecond time scales.