Issue 27, 2023

Enhanced water transportation on a superhydrophilic serial cycloid-shaped pattern

Abstract

Spontaneous and directional water transportation (SDWT) is considered as an ideal water transportation method and has a great prospect in the aerospace and ship fields. Nonetheless, the existing SDWT has the limitation of a slow water transportation velocity because of its geometry structure configuration, which hinders the practical application of the SDWT. To overcome this limitation, we developed a new superhydrophilic serial cycloid-shaped pattern (SSCP) which was inspired by the micro-cavity shape of the Nepenthes. First, we experimentally found that the water transportation velocity on the SSCP was faster than that on the superhydrophilic serial wedge-shaped pattern (SSWP) and analyzed the faster water transportation mechanism. Then, the influence of the SSCP parameters on the transportation velocity was investigated by a single-factor experiment. In addition, the water transportation velocity on the SSCP was enhanced to 289 mm s−1 by combining the single-factor experiment, orthogonal optimization design, streamline junction transition optimization, and pre-wet pattern, which was the fastest in the SDWT. Moreover, the SSCP demonstrated its superior capability in long-distance water transportation, gravity resistant water transportation, heat transfer, and fog collection. This finding shows remarkable application prospects in the high-performance fluid transportation system.

Graphical abstract: Enhanced water transportation on a superhydrophilic serial cycloid-shaped pattern

Supplementary files

Article information

Article type
Paper
Submitted
11 May 2023
Accepted
02 Jun 2023
First published
05 Jun 2023

Nanoscale, 2023,15, 11473-11481

Enhanced water transportation on a superhydrophilic serial cycloid-shaped pattern

D. Yan, Y. Lu, J. Liu, Y. Chen, J. Sun and J. Song, Nanoscale, 2023, 15, 11473 DOI: 10.1039/D3NR02180G

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