Electrowetting-on-dielectric powered by triboelectric nanogenerator

Electrowetting-on-dielectric (EWOD) is a versatile technique for controlling the liquid-wetting behavior of solid surfaces, but usually relies on bulky and complex power suppliers for high driving voltages, which largely limits the practical applications toward miniaturization, portability, and multifunctional integration. Here, a mechanical stimuli-controlled EWOD strategy powered by a triboelectric nanogenerator (TENG) with tunable highvoltage output is demonstrated, which allows for manipulating liquid wettability by mechanical stimuli. The physical behaviors of the voltage transfer and contact angle response during the TENG-driven EWOD process are experimentally investigated, and the underlying mechanisms are revealed by a circuit model, which can give general guidance for the design and optimization of the mechanical stimuli-controlled EWOD systems. As a derived application of this strategy to the microfabrication field, a self-powered electrocapillary infilling and micromolding method is further developed, which allows for fabricating the originally difficult-to-mold microstructures in a handy way. This mechanical stimuli-controlled TENG-driven EWOD strategy also shows general applicability for different liquid systems of not only the liquid prepolymer but also the DI water and ionic liquid, which can potentially extend to more functional applications involving tunable wettability or liquid infilling/ permeation, such as wearable microfluidics or lab-on-chip, electrolyte infilling for porous electrodes, and ondemand drug permeation systems.

Automated summary

The paper demonstrates a mechanical stimuli-controlled EWOD strategy powered by a triboelectric nanogenerator (TENG) with tunable high voltage output. It investigates the physical behaviors and underlying mechanisms of TENG-driven EWOD process and develops a self-powered electrocapillary infilling and micromolding method as an application. The strategy shows general applicability for different liquid systems and can potentially be used in wearable microfluidics, electrolyte infilling, and drug permeation systems.