Thickness-dependent fast wetting transitions due to the atomic layer deposition of zinc oxide on a micro-pillared surface.

Libing Duan,Yajie Yang,Sihang Yang,Yanbo Xie,Xiangyang Ji,Xinjun Lv

doi:10.1039/c9ra08498c

Libing Duan, Yajie Yang + Show 4 more

Open Access

https://doi.org/10.1039/c9ra08498c

Copy DOI

Journal: RSC advances	Publication Date: Jan 1, 2020
Citations: 10	License type: CC BY 3.0

Affiliation: Northwestern Polytechnical University

Abstract

Smart surfaces promote the fundamental understanding of wetting and are widely used in practical applications for energy and water collection. Light-induced switchable wettability facilitated by ZnO coatings, for instance, was developed for liquid manipulation at the surface. However, the transition of wetting states was reported to follow a hydrophobic–hydrophilic cycle in an hour, which is very long and may limit its future applications. We recently discovered that the cycle of the wetting state transitions on inorganic coatings can be shortened to less than 100 seconds by using ALD-coated ZnO on a pillared surface. However, the mechanisms are still unclear. Here, we investigated the effects of coating thickness on the transition speed and found that it significantly depended on the thickness of the coating with the optimal thickness less than 50 nm. We found that the minimum critical time for a wetting state transition cycle was less than 50 seconds with a thickness of 40 nm. Although the transition time of surfaces with coatings over 70 nm thickness remained constant at 10 min for a cycle, it was shorter than those of other deposition techniques for a coarse surface. Here, we propose a “penetration–diffusion” model to explain the fast and thickness-dependent wetting transitions. Our study may provide a new paradigm for fast wetting transition surfaces with cycle time within tens of seconds using a homogeneous thin layer coated on a rough surface.

Highlights

Wetting is a fundamental phenomenon, which has been studied for many decades.[1]
We found that the exponential decay function tted well with the contact angle (CA) values measured as a function of time: q 1⁄4 q0 þ A exp
; where q0, A, K are the saturated value at the hydrophilic state, the constant value obtained by tting, the critical transition time to attain saturation, which represents the speed of transition

Summary

Introduction

Wetting is a fundamental phenomenon, which has been studied for many decades.[1]. Inspired by the features of natural materials, many new materials and technologies have been invented to enable a smart-control of wetting states using arti cial structures.[2,3,4] The transition of materials between hydrophilic and hydrophobic states has attracted attention for its wide applications, such as self-cleaning,[5] anti-fog coating,[6] liquid transport[7] and micro uidics.[8,9] An external stimulus induces a change in the surface energy of materials, resulting in wettability transitions.

Results

Discussion

Conclusion