Meng Hua scite author profile

Engineering the dropwise condensation of water on surfaces is critical in a wide range of applications from thermal management (e.g. heat pipes, chip cooling etc.) to water harvesting technologies. Surfaces that enable both efficient droplet nucleation and droplet self‐removal (i.e. droplet departure) are essential to accomplish successful dropwise condensation. However it is extremely challenging to design such surfaces. This is because droplet nucleation requires a wettable surface while droplet departure necessitates a super‐hydrophobic surface. Here we report that these conflicting requirements can be satisfied using a hierarchical (multiscale) nanograssed micropyramid architecture that yield a gobal superhydrophobicity as well as locally wettable nucleation sites, allowing for ˜65% increase in the drop number density and ˜450% increase in the drop self‐removal volume as compared to a superhydrophobic surface with nanostructures alone. Further we find that synergistic co‐operation between the hierarchical structures contributes directly to a continuous process of nucleation, coalescence, departure, and re‐nucleation enabling sustained dropwise condensation over prolonged periods. Exploiting such multiscale coupling effects can open up novel and exciting vistas in surface engineering leading to optimal condensation surfaces for high performance electronics cooling and water condenser systems.

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A mixed lubrication model for studying tribological behaviors of surface texturing

Zhang

Hua

Dong

et al. 2016

Tribology International

137

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Experimental investigation of reflection in guided wave-based inspection for the characterization of pipeline defects

Wang

Tse

Mechefske

et al. 2010

NDT & E International

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Boundary slip surface design for high speed water lubricated journal bearings

Zhou

Hua

Dong

et al. 2014

Tribology International

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A Study on the Tribological Behavior of Surface Texturing on Babbitt Alloy under Mixed or Starved Lubrication

Zhang

Hua

et al. 2014

Tribol Lett

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Meng Hua

Nanograssed Micropyramidal Architectures for Continuous Dropwise Condensation

A mixed lubrication model for studying tribological behaviors of surface texturing

Experimental investigation of reflection in guided wave-based inspection for the characterization of pipeline defects

Boundary slip surface design for high speed water lubricated journal bearings

A Study on the Tribological Behavior of Surface Texturing on Babbitt Alloy under Mixed or Starved Lubrication

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