A combined structural and wettability gradient surface for directional droplet transport and efficient fog collection

Hypothesis: The droplet manipulation behavior is affected by chemical structural driving force (including the superposition of electric, magnetic, optical and thermal fields), which directly determine transporta-tion velocity. A lot of research has focused on a single driving force that induces the directional trans-portation behavior, which affects its performance. Experiments: A simple method for preparing wettability gradient conical copper needles (WGCCN) com-bining structural gradient and chemical gradient was formulated. The effect of droplet volume and tilt angles on droplet transport velocity was systematically studied. The process of droplet transport was revealed through theoretical model and mechanical analysis. Finally, the application of WGCCN and its array model in fog collection were explored. Findings: A continuous chemical gradient in the conical structure gradient induces the droplet directional transportation, and the transportation velocity depends on the droplet volume. In addition, under the cooperation effect of multiple driving force, the droplet can still be transported in a directional orientation even if it is tilted at a certain angle. The simple droplet manipulation behavior portends that the droplets directional transport behavior can be applied in microfluidic manipulation by cooperation of effective multiple driving force with satisfactory results. (c) 2021 Elsevier Inc. All rights reserved.

Automated summary

The research reveals that the behavior of droplet manipulation is influenced by chemical structural driving force, with transportation velocity depending on droplet volume. Under the cooperation of multiple driving forces, droplets can still be transported directionally even when titled.