Experimental Investigation of Condensation and Freezing Phenomenon on Hydrophilic and Hydrophobic Titanium Nanopillared Glass Surfaces

Atmospheric condensation is very important for multiple practical applications such as heat transfer, thermal management, aerospace, and condensate harvesting. Water droplets heterogeneously nucleate on the surfaces when the temperature is below the dew point temperature. The nucleation energy barri...

Full description

Saved in:
Bibliographic Details
Published inHeat transfer engineering Vol. 42; no. 6; pp. 533 - 548
Main Authors Rejaul Haque, Mohammad, Zhu, Chen, Qu, Chuang, Kinzel, Edward C., Rachel Betz, Amy
Format Journal Article
LanguageEnglish
Published Philadelphia Taylor & Francis 26.03.2021
Taylor & Francis Ltd
Subjects
Coalescing
Condensates
Condensation
Dew point
Droplets
Freezing
Humidity
Morphology
Nucleation
Photolithography
Polytetrafluoroethylene
Relative humidity
Size distribution
Surface properties
Thermal management
Titanium
Water drops
Wetting
Online AccessGet full text

Cover

More Information
Summary:Atmospheric condensation is very important for multiple practical applications such as heat transfer, thermal management, aerospace, and condensate harvesting. Water droplets heterogeneously nucleate on the surfaces when the temperature is below the dew point temperature. The nucleation energy barrier for a condensed droplet varies significantly with the humidity content in the operating environment. The freezing of this condensate is also dependent on the operating conditions and surface properties. This article presents an experimental study of condensation and freezing from humid air with the objective of understanding how the surface morphology and chemistry determines the droplet shape and wetting state. Hexagonal close-packed arrays of titanium (Ti) pillars are patterned using microsphere photolithography (MPL). The Ti nanostructured surface was tested with and without a Teflon © coating to reveal the condensate harvesting, passive freezing, and dropwise condensation applications, respectively. Condensation and freezing tests were conducted in the presence of non-condensable gases (air) with different relative humidity (RH) levels to control the nucleation site density. The experiments showed that droplet growth occurs in the following stages: initial nucleation, direct growth, and coalescence events. By pinning droplets, coalescence is suppressed for the Ti nanopillared surface altering the size distribution of droplets and significantly accelerating the freezing process.
ISSN:0145-7632
1521-0537
DOI:10.1080/01457632.2019.1707401