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Jumping liquid metal droplets controlled electrochemically

Minyung Song, Nazgol Mehrabian, Sahil Karuturi, Michael D. Dickey

2021Applied Physics Letters29 citationsDOI

Abstract

Jumping droplets are interesting because of their applications in energy harvesting, heat transfer, anti-icing surfaces, and displays. Typically, droplets “jump” from a surface when two or more drops coalesce. Here, we demonstrate an approach to get a single droplet of liquid metal (eutectic gallium indium) to jump by using electrochemistry in a solution of 1M NaOH. Applying a positive potential to the metal (∼1 V relative to the open circuit potential) drives electrochemical surface oxidation that lowers the interfacial tension from ∼450 mN/m to ∼0 mN/m. In the low interfacial tension state, the droplet flattens due to gravity. Rapid switching to a negative potential (relative to the open circuit potential) reduces the surface oxide, returning the deformed droplet to a state of high interfacial tension. This rapid change in interfacial tension in the flattened state generates excess surface energy, which drives the droplet to return to a spherical shape with enough momentum that the liquid droplet jumps. This work is unique because (1) the jumping is controlled and tuned electrically, (2) the approach works with a single droplet, (3) it does not require a superhydrophobic surface, which is typically used to prevent droplets from adhering to the substrate, (4) the drops jump through a viscous medium rather than air, and (5) the potential energy obtained by the jumping drops is one order of magnitude higher than previous approaches. Yet, a limitation of this approach relative to conventional jumping drops is the need for electrolyte and a source of electricity to enable jumping. Herein, we characterize and optimize the jumping height (∼6 mm for a 3.6 mm diameter drop) by changing the reductive and oxidative potential and time.

Topics & Concepts

Surface tensionJumpingMaterials scienceElectrochemical potentialJumpElectrolyteLiquid metalSurface energyChemical physicsMechanicsElectrochemistryNanotechnologyChemistryComposite materialThermodynamicsElectrodePhysicsBiologyPhysical chemistryPhysiologyQuantum mechanicsElectrowetting and Microfluidic TechnologiesSurface Modification and SuperhydrophobicityModular Robots and Swarm Intelligence
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