Issue 6, 2020

Under-oil self-driven and directional transport of water on a femtosecond laser-processed superhydrophilic geometry-gradient structure

Abstract

Self-driven and continuous directional transport of water droplets in an oil environment has great potential applications in microfluidics, oil–water separation, etc. Nevertheless, most current studies exploit water behaviors occurring in air, and the directional regulation of water in a viscous oil medium remains a challenge. In this work, a superhydrophilic geometry-gradient stainless steel platform with nanoparticle-covered nanoripple structures is proposed using femtosecond laser direct writing technology. The as-prepared platform spontaneously and directionally transported water droplets in the oil environment from the minor side to the large side of the trapezoidal platform surface, but not in the opposite direction. The transport velocity of water droplets as a function of trapezoid angle and tilt angle of the as-prepared platform was investigated in detail. In addition, a pumpless under-oil water transport platform was successfully prepared on other substrates including Ti and Ni sheets, polyimide film, and C cloth, and exhibited transport capabilities when the platform was flexed and combined into various shapes. This work offers insight into the simple fabrication of a flexible and substrate-independent pumpless under-oil directional transport device for water.

Graphical abstract: Under-oil self-driven and directional transport of water on a femtosecond laser-processed superhydrophilic geometry-gradient structure

Supplementary files

Article information

Article type
Paper
Submitted
20 Nov. 2019
Accepted
27 Jan. 2020
First published
27 Jan. 2020

Nanoscale, 2020,12, 4077-4084

Under-oil self-driven and directional transport of water on a femtosecond laser-processed superhydrophilic geometry-gradient structure

J. Wu, K. Yin, M. Li, Z. Wu, S. Xiao, H. Wang, J. Duan and J. He, Nanoscale, 2020, 12, 4077 DOI: 10.1039/C9NR09902F

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