Condensations on electrowetting surfaces: An electrostatic liquid conveyor from dropwise-filmwise competition

In contrast to the traditional point of view, electrowetting creates a dynamic wetting regime. Hydrophilicity can penetrate or recede from the working surface -depending on the liquid locale rather than the substrate structures. Size regulation forms droplet clusters as condensation accumulates. Coalescence cascades and mass imbalances transfer the liquid from one zone to the next. What ensues is a passive electrostatic liquid conveyor that takes the condensation away from its constant self-stagnating cycles. Each working zone functions independently from one another according to its intended purpose: nucleation and diffusion, accumulation and collection. 40 to 50 percent of the increase in liquid recovery traces its root to the spatial-size regulation of the droplet population. Simultaneously, the gain from higher nucleations runs parabolically with electrostatic voltage. The competition between dropwise and filmwise tendencies determines the migration of condensates. Yet, the autonomy of the two means that nucleations are direct and unhindered as to how high an electrostatic voltage can be: the only limit is the material strength and endurance to sustain this concentration of electric potentials. & COPY; 2023 Elsevier Ltd. All rights reserved.

Automated summary

In contrast to traditional point of view, electrowetting allows for dynamic wetting regime, where hydrophilicity can penetrate or recede based on liquid location rather than substrate structure. Droplets form clusters through size regulation as condensation accumulates and are transferred by coalescence cascades and mass imbalances. This passive electrostatic liquid conveyor enables the removal of condensation from self-stagnating cycles. Each working zone functions independently for nucleation and diffusion, accumulation and collection. 40 to 50 percent of the liquid recovery increase is attributed to spatial-size regulation, while higher nucleations are influenced by electrostatic voltage. The migration of condensates is determined by the competition between dropwise and filmwise tendencies. The autonomy of nucleations allows for unhindered electrostatic voltage, limited only by material strength and endurance. © 2023 Elsevier Ltd. All rights reserved.