Species Transport Driven by Droplet Impact in Wavy Thin Films

TL;DR

This study investigates how residual capillary waves on thin liquid films influence droplet impact dynamics and mixing, revealing asymmetries governed by wave phase and amplitude, with effects diminishing at higher Weber numbers.

Contribution

It introduces controlled wave disturbances to study impact behavior, demonstrating how traveling waves alter impact symmetry and mixing compared to quiescent films.

Findings

Impact asymmetry depends on wave phase and amplitude.

Droplet impact on wavy films causes asymmetric cavity collapse and jet formation.

Inertial effects at high Weber numbers reduce wave-induced impact asymmetries.

Abstract

Droplet impact on thin liquid films is commonly studied on quiescent surfaces, although practical systems often involve residual capillary waves generated by preceding droplets. This study examines how such traveling waves modify impact dynamics and mixing. Controlled surface disturbances were produced using an acoustic excitation system that replicated droplet-induced waves, and a two-color laser-induced fluorescence method was implemented to obtain simultaneous measurements of film thickness and dye concentration. Impacts on wavy films deviated markedly from quiescent conditions. Rim evolution, cavity collapse, and jet formation became asymmetric, governed by the phase of the wave relative to the impact. These behaviors were linked to local variations in film depth, which redirected cavity retraction and the associated mixing flow. Reconstructed concentration fields confirmed that droplet liquid is displaced according to these depth gradients, producing asymmetric mixing at moderate Weber numbers. A dimensionless asymmetry index quantified the dependence on wave amplitude, phase, and distance from the acoustic wave generator. At higher Weber numbers, inertial mixing attenuated these effects, and the dynamics approached those of static films.