Wetting transition in laser-fabricated hierarchical surface structures and its impact on condensation heat transfer characteristics

Graphical abstract (a) represents the laser setup, Silane, FESEM, 3D image, contact angle and condensation images of different surfaces at 20 K subcooling (b) indicates the HTC values of different surfaces at 1 K subcooling and departure diameter, departure frequency and heat flux of different surfa...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2019-09, Vol.140, p.886-896
Main Authors: Venkata Krishnan, D., Udaya Kumar, G., Suresh, S., Jubal, M., Thansekhar, M.R., Ramesh, Ravi
Format: Article
Language:English
Subjects:
Aspect ratio
Condensation
Condensation heat transfer
Contact angle
Copper
Droplet parameters
Droplets
Grooves
Heat flux
Heat transfer
Heat transfer coefficients
Hydrophobic surfaces
Hydrophobicity
Integrated effect
Lasers
Morphology
Picosecond laser
Silane coating
Structural hierarchy
Vaporization
Wettability
Wetting
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Summary:Graphical abstract (a) represents the laser setup, Silane, FESEM, 3D image, contact angle and condensation images of different surfaces at 20 K subcooling (b) indicates the HTC values of different surfaces at 1 K subcooling and departure diameter, departure frequency and heat flux of different surface at 20 K subcooling. [Display omitted] •Integrated effect of laser structuring and silane improved the HTC values by ∼90%.•Mountain like structures were formed only above strong threshold value of copper.•Departure diameter reduced by half and departure frequency increased by ∼250%.•Increase in the Laplace pressure gradient was attributed for the enhancement. Investigation on the fabrication of superhydrophobic surfaces to maintain dropwise condensation, which possess higher degree of heat transfer than filmwise condensation, has become an ineludible area of research. In this work, we have attained superhydrophobicity in plain copper using picosecond laser treatment and silane coating through vaporisation technique and the effects of the same in condensation heat transfer has been studied. Depth of the grooves attained on the surface was changed by varying the laser power. Contact angle and FESEM images were used to characterise the wettability and surface morphologies respectively. Silane coated laser structured samples attained superhydrophobicity, whereas laser structured samples attained a maximum contact angle value of 143°. Condensation experiment was then carried on the as-prepared samples in a dedicated setup and were compared against the bare copper surface to evaluate its performance. Nusselt's theory was used to validate the obtained results by comparing it aginst bare copper surface. All the modified test specimens produced superior results than the untreated surface, but the silane coated surface with maximum depth resulted in 97% and 88% enhancement in heat flux and heat transfer coefficient values respectively. Microstructure formation during laser structuring and increase in the aspect ratio due to increase in groove depth resulted in the increase of Laplace pressure gradient, pushing the droplet to a critical state, that is partial wetting state known as micro-Wenzel nano-Cassie state. Gravity, buoyancy and dispersive adhesion forces then acts on the droplet and detaches it from the surface at much smaller diameter, increasing the droplet sweeping cycle. Droplet departure diameter reduced nearly 2 times and the departure frequency increased by
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2019.06.005