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Under-liquid dual superlyophobic nanofibrous polymer membranes achieved by coating thin-film composites: a design principle.


ABSTRACT: Surfaces with under-liquid dual superlyophobicity have garnered tremendous interest because of their promising applications, but their unexplored underlying nature restricts the designed construction of such surfaces. Herein, we coated the thin-film composites with different terminal groups over the electrospun polyacrylonitrile nanofibrous membranes, which afforded the membranes excellent stability in organic solvents, as well as modulated under-liquid wetting behaviors. Among them, the representative under-liquid dual superlyophobic 4-cyan-Ph-terminated membrane could realize highly efficient separation of all types of oil/water mixtures and even emulsions. Moreover, we found that the under-liquid wetting behaviors could be classified in terms of the intrinsic water contact angle (? w). By comparing the total interfacial energy, we proved that the under-liquid dual lyophobic surfaces were thermodynamically metastable. On this basis, we could predict the ? w of rough surfaces with the under-liquid dual lyophobicity in a given oil-water-solid system (e.g., 47.3-89.1° in cyclohexane-water-solid system, R = 2). This work provides a design principle for the fabrication of under-liquid dual superlyophobic surfaces, which will open potential applications in diverse fields in terms of such smart surfaces.

SUBMITTER: Wang Q 

PROVIDER: S-EPMC6610571 | biostudies-literature | 2019 Jul

REPOSITORIES: biostudies-literature

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Under-liquid dual superlyophobic nanofibrous polymer membranes achieved by coating thin-film composites: a design principle.

Wang Qifei Q   Wang Yang Y   Wang Baixian B   Liang Zhiqiang Z   Di Jiancheng J   Yu Jihong J  

Chemical science 20190520 25


Surfaces with under-liquid dual superlyophobicity have garnered tremendous interest because of their promising applications, but their unexplored underlying nature restricts the designed construction of such surfaces. Herein, we coated the thin-film composites with different terminal groups over the electrospun polyacrylonitrile nanofibrous membranes, which afforded the membranes excellent stability in organic solvents, as well as modulated under-liquid wetting behaviors. Among them, the represe  ...[more]

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