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Engineered Switchable‐Wettability Surfaces for Multi‐Path Directional Transportation of Droplets and Subaqueous Bubbles

Dongdong Xie, Yunna Sun, Yongjin Wu, Kai Wang, Guilian Wang, Faheng Zang, Guifu Ding

2022Advanced Materials36 citationsDOI

Abstract

Conventional engineered surfaces for fluid manipulation are hindered by the set wettability, and thus they can only achieve spontaneous transport of single-phase fluid, namely liquid or gas. Moreover, fluid transport systems that are robust to path defects have yet to be fully explored. Here, unprecedentedly, a universal wettability switching strategy is developed for achieving programmable directional transport of both droplets and subaqueous bubbles on a dumbbell-patterned functional surface (DPFS), featuring in strong robustness, high efficiency, and effective cost. By tuning the superwettability of DPFS through octadecyltrichlorosilane treatment and ultraviolet-C selective irradiation, the transport fluid can alternate between liquid and gas. The material's switchable superwettability regulates the fluid directed dynamics within the confined pattern, in which the sustaining fluid propelling relies on the surface energy difference between the starting and terminal sites. This enables the construction of multiple channels, which works synergistically with ultralow-volume-loss transport to impart the fluidic system with strong robustness against path defects. Underlying the completion of complex microfluidics tasks, spatially-selective cooling devices and subaqueous gas microreactors are successfully demonstrated. This energy-consumption-free fluid transport system opens a new avenue for on-chip programmable fluid manipulation, promoting innovative applications requiring rational control of two-phase fluid transport.

Topics & Concepts

WettingMaterials scienceNanotechnologyBubblePath (computing)Chemical engineeringContact angleComposite materialMechanicsEngineeringProgramming languageComputer sciencePhysicsSurface Modification and SuperhydrophobicityFluid Dynamics and Heat TransferInnovative Microfluidic and Catalytic Techniques Innovation