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Efficient Gas Transportation Using Bioinspired Superhydrophobic Yarn as the Gas-Siphon Underwater

Xiaolong Zhang, Yang Dong, Zhao He, Han‐Yuan Gong, Xiang Xu, Meiyun Zhao, Hongling Qin

2020ACS Applied Materials & Interfaces24 citationsDOI

Abstract

, we prepared a superhydrophobic yarn with a fiber network structure via a facile and environmentally friendly method. Attributed to the low surface energy, the superhydrophobic fiber network structure on the yarn is able to trap and transport bubbles directionally underwater. The functional yarn has good superhydrophobic and superaerophilic properties underwater to realize the directional transport of bubbles underwater without being pumped. We designed demonstration experiments on the antibuoyancy directional bubble transportation, which indicated the feasibility in the applications of gas-related fields. Significantly, on further testing, where the superhydrophobic yarn is put into a U-shaped pipe, we obtain a gas-siphon underwater with a high flux. The superhydrophobic fiber structure yarn can trap the gas underwater to enable the self-starting behavior while no manual intervention is used. The gas-siphon can convey gas over the edge of a vessel and deliver it at a higher level without energy input, which is driven by the differential pressure. The relationship between the differential pressure and the volume flux of transport bubbles is investigated. The experimental results show that the prepared superhydrophobic yarn has the advantages of good stability, easy preparation, and low cost in bubble continuous transportation underwater, which provides a novel strategy for the development and application of new technologies such as directional transportation, separation, exhaustion, and collection of gases in water.

Topics & Concepts

UnderwaterMaterials scienceBubbleFiberVolume (thermodynamics)Siphon (mollusc)YarnNanotechnologyMarine engineeringComposite materialComputer scienceEngineeringPhysicsBiologyParallel computingOceanographyEcologyQuantum mechanicsGeologySurface Modification and SuperhydrophobicityFluid Dynamics Simulations and InteractionsFluid Dynamics and Heat Transfer
Efficient Gas Transportation Using Bioinspired Superhydrophobic Yarn as the Gas-Siphon Underwater | Litcius