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Flexible Transparent Hierarchical Nanomesh for Rose Petal-Like Droplet Manipulation and Lossless Transfer

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Authors

Wong, William
Nasiri, Noushin
Liu, Guanyu
Rumsey-Hill, Nicholas
Craig, Vincent
Nisbet, David
Tricoli, Antonio

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Wiley - VCH Verlag GmbH & CO. KGaA

Abstract

Precise manipulation of water is a key step in numerous natural and synthetic processes. Here, a new flexible and transparent hierarchical structure is determined that allows ultra-dexterous manipulation and lossless transfer of water droplets. A 3D nanomesh is fabricated in one step by scalable electrospinning of low-cost polystyrene solutions. Optimal structures are composed of a mesh of dense nanofiber layers vertically separated by isolated mesoporous microbeads. This results in a highly adhesive superhydrophobic wetting that perfectly mimics rose petal-like structures. Structural-functional correlations are obtained over all key process parameters enabling robust tailoring of the wetting properties from hydrophilic to lotus-like Cassie-Baxter and rose-like Cassie-impregnating states. A mechanistic model of the droplet adhesion and release dynamics is obtained alongside the first demonstration of a mechanically induced transfer of microdroplets between two superhydrophobic coatings. This low-temperature reaction-free material structure demonstrates a facile means to fabricate impenetrable residue-less rose petal-like surfaces with superhydrophobic contact angles of 152 ± 2°and effective adhesion strength of 113 ± 20 μN. This is a significant step toward parallel, multistep droplet manipulation with applications ranging from flexible on-paper devices to microfluidics and portable/wearable biosensors.

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Advanced Materials Interfaces

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Restricted until

2037-12-31