Ultrahigh Subcooling Dropwise Condensation Heat Transfer on Slippery Liquid-like Monolayer Grafted Surfaces

Rapid and continuous droplet shedding is crucial for many applications, including thermal management, water harvesting, and microfluidics, among others. Superhydrophobic surfaces, though effective, suffer from droplet pinning at high subcooling temperature (T sub). Conversely, slippery liquid-like s...

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Bibliographic Details
Published in:ACS applied materials & interfaces 2024-10, Vol.16 (39), p.53285-53298
Main Authors: Huang, Ting-en, Lu, Yisheng, Wei, Zhaozhuo, Li, Dawei, Li, Qin-Yi, Wang, Zhenying, Takahashi, Koji, Orejon, Daniel, Zhang, Peng
Format: Article
Language:English
Subjects:
adhesion
chemical bonding
contact angle
droplets
durability
heat transfer
heat transfer coefficient
hydrophobicity
hysteresis
microfluidic technology
polymers
silicon
surface temperature
Surfaces, Interfaces, and Applications
transmission electron microscopy
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Summary:Rapid and continuous droplet shedding is crucial for many applications, including thermal management, water harvesting, and microfluidics, among others. Superhydrophobic surfaces, though effective, suffer from droplet pinning at high subcooling temperature (T sub). Conversely, slippery liquid-like surfaces covalently bonded with flexible hydrophobic molecules show high stability and low droplet adhesion attributed to their dense and ultrasmooth water repellent polymer chains, enhancing dropwise condensation and rapid shedding. In this work, linear poly­(dimethylsiloxane) chains of various viscosities are covalently bonded onto silicon substrates to form thin and smooth monolayer coated surfaces. The formation of the monolayer is characterized by cryogenic transmission electron microscopy. On these surfaces a very low contact angle hysteresis is reported within wide surface temperature ranges as well as continuous dropwise condensation at ultrahigh T sub of 60 K. In particular, one of the highest condensation heat fluxes of 1392.60 kW·m–2 and a heat transfer coefficient of 23.21 kW·m–2·K–1 at ultrahigh T sub of 60 K is reported. The experimental heat transfer performance is further compared to the theoretical heat transfer via the individual droplets with the droplet distribution elucidated via both macroscopic observations as well as environmental scanning electron microscopy. Finally, only a mild decrease in the heat transfer coefficient of 20.3% after 100 h of condensation test at T sub of 60 K is reported. Slippery liquid-like surfaces promote droplet shedding and sustain dropwise condensation at high T sub without flooding empowered by the lower frictional forces, addressing challenges in heat transfer performance and durability.
ISSN:1944-8244
1944-8252
1944-8252
DOI:10.1021/acsami.4c12220