Spontaneous Wenzel to Cassie dewetting transition on structured surfaces

Bo Zhang; Xuemei Chen; Jure Dobnikar; Zuankai Wang; Xianren Zhang

doi:10.1103/PhysRevFluids.1.073904

Spontaneous Wenzel to Cassie dewetting transition on structured surfaces

Bo Zhang^*, Xuemei Chen, Jure Dobnikar, Zuankai Wang, Xianren Zhang

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

48 Citations (Scopus)

Abstract

Most superhydrophobic surfaces undergo a wetting transition from the Cassie to the Wenzel state, either spontaneously or under the action of external perturbations. The reverse dewetting transition is hampered by a large energy barrier and in order to achieve it, external fields are usually applied. Here we perform experiments, theoretical analysis, and lattice Boltzmann simulations of droplet condensation on a patterned superhydrophobic surface and demonstrate that the dewetting energy barrier can be reduced by manipulating the adhesion forces. Moreover, the kinetics of dewetting is a result of a subtle interplay of wetting and adhesion and in certain geometries, such as cone- shaped texture, the dewetting transition from Wenzel to Cassie state becomes spontaneous.

Original language	English
Article number	073904
Journal	Physical Review Fluids
Volume	1
Issue number	7
Online published	29 Nov 2016
DOIs	https://doi.org/10.1103/PhysRevFluids.1.073904
Publication status	Published - Nov 2016

Funding

This work was supported by the National Natural Science Foundation of China (Grants No. 21276007 and No. 91434204).

Research Keywords

SUPERHYDROPHOBIC SURFACES
NANOSTRUCTURED SURFACES
DROPWISE CONDENSATION
WATER STRIDERS
MICRODROPLETS
STATES
DROPS
ROUGHNESS
EQUATION
DROPLETS

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title = "Spontaneous Wenzel to Cassie dewetting transition on structured surfaces",

abstract = "Most superhydrophobic surfaces undergo a wetting transition from the Cassie to the Wenzel state, either spontaneously or under the action of external perturbations. The reverse dewetting transition is hampered by a large energy barrier and in order to achieve it, external fields are usually applied. Here we perform experiments, theoretical analysis, and lattice Boltzmann simulations of droplet condensation on a patterned superhydrophobic surface and demonstrate that the dewetting energy barrier can be reduced by manipulating the adhesion forces. Moreover, the kinetics of dewetting is a result of a subtle interplay of wetting and adhesion and in certain geometries, such as cone- shaped texture, the dewetting transition from Wenzel to Cassie state becomes spontaneous.",

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author = "Bo Zhang and Xuemei Chen and Jure Dobnikar and Zuankai Wang and Xianren Zhang",

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doi = "10.1103/PhysRevFluids.1.073904",

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AU - Zhang, Bo

AU - Chen, Xuemei

AU - Dobnikar, Jure

AU - Wang, Zuankai

AU - Zhang, Xianren

PY - 2016/11

Y1 - 2016/11

N2 - Most superhydrophobic surfaces undergo a wetting transition from the Cassie to the Wenzel state, either spontaneously or under the action of external perturbations. The reverse dewetting transition is hampered by a large energy barrier and in order to achieve it, external fields are usually applied. Here we perform experiments, theoretical analysis, and lattice Boltzmann simulations of droplet condensation on a patterned superhydrophobic surface and demonstrate that the dewetting energy barrier can be reduced by manipulating the adhesion forces. Moreover, the kinetics of dewetting is a result of a subtle interplay of wetting and adhesion and in certain geometries, such as cone- shaped texture, the dewetting transition from Wenzel to Cassie state becomes spontaneous.

AB - Most superhydrophobic surfaces undergo a wetting transition from the Cassie to the Wenzel state, either spontaneously or under the action of external perturbations. The reverse dewetting transition is hampered by a large energy barrier and in order to achieve it, external fields are usually applied. Here we perform experiments, theoretical analysis, and lattice Boltzmann simulations of droplet condensation on a patterned superhydrophobic surface and demonstrate that the dewetting energy barrier can be reduced by manipulating the adhesion forces. Moreover, the kinetics of dewetting is a result of a subtle interplay of wetting and adhesion and in certain geometries, such as cone- shaped texture, the dewetting transition from Wenzel to Cassie state becomes spontaneous.

KW - SUPERHYDROPHOBIC SURFACES

KW - NANOSTRUCTURED SURFACES

KW - DROPWISE CONDENSATION

KW - WATER STRIDERS

KW - MICRODROPLETS

KW - STATES

KW - DROPS

KW - ROUGHNESS

KW - EQUATION

KW - DROPLETS

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U2 - 10.1103/PhysRevFluids.1.073904

DO - 10.1103/PhysRevFluids.1.073904

M3 - RGC 21 - Publication in refereed journal

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VL - 1

JO - Physical Review Fluids

JF - Physical Review Fluids

IS - 7

M1 - 073904

ER -

Spontaneous Wenzel to Cassie dewetting transition on structured surfaces

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Research Keywords

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