Microdroplet self-propulsion during dropwise condensation on lubricant-infused surfaces
Jianxing Sun, Patricia Weisensee

TL;DR
This study reveals that microdroplets on lubricant-infused surfaces self-propel due to capillary forces, enhancing droplet sweeping and heat transfer during water vapor condensation.
Contribution
It uncovers the mechanism of gravity-independent microdroplet self-propulsion driven by lubricant menisci, with quantitative analysis linking velocity to droplet size and oil viscosity.
Findings
Microdroplets as small as 2 μm undergo self-propulsion.
Maximum droplet velocity is inversely proportional to oil viscosity.
Self-propulsion enhances droplet sweeping and heat transfer efficiency.
Abstract
Water vapor condensation is common in nature and widely used in industrial applications, including water harvesting, power generation, and desalination. As compared to traditional filmwise condensation, dropwise condensation on lubricant-infused surfaces (LIS) can lead to an order-of-magnitude increase in heat transfer rates. Small droplets (with the diameter below 100 m) account for nearly 85 percent of the total heat transfer and droplet sweeping plays a crucial role in clearing nucleation sites, allowing for frequent re-nucleation. Here, we focus on the dynamic interplay of microdroplets with the thin lubricant film during water vapor condensation on LIS. Coupling high-speed imaging, optical microscopy, and interferometry, we show that the initially uniform lubricant film re-distributes during condensation. Governed by lubricant height gradients, microdroplets as small as 2…
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