Superwetting photothermal membranes enabled by polyphenol-mediated nanostructured coating with raspberry-like architectures for solar-driven interfacial evaporation

Solar-driven interfacial evaporation, as an emerging solar thermal utilization technology for water production, provides an opportunity for alleviate water-energy nexus. Superwetting membranes, as famous interface materials, combine hierarchical micro-nano architectures and open-porous structures th...

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Bibliographic Details
Published in:Desalination 2022-11, Vol.542, p.116046, Article 116046
Main Authors: Zhao, Xueting, Wang, Tingyuan, Wang, Ruoxi, Lan, Youyou, Jiang, Yuanyuan, Pan, Jiefeng
Format: Article
Language:English
Subjects:
Membrane
Photothermal
Polyphenol
Solar-driven interfacial evaporation
Superwetting
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Summary:Solar-driven interfacial evaporation, as an emerging solar thermal utilization technology for water production, provides an opportunity for alleviate water-energy nexus. Superwetting membranes, as famous interface materials, combine hierarchical micro-nano architectures and open-porous structures that enable high-efficient solar-driven interfacial evaporation. Herein, the design and synthesis of photothermal membranes with polyphenol-mediated nanostructured coating by integrating the tannic acid (TA)-polyethyleneimine (PEI) complexation and the oxidation-mediated TA-FeII complexation is reported. The assembled TA-PEI/FeII/III coating features hierarchical raspberry-like architectures derived from the TA-PEI nanoconjugates and the oxidized metal-organic hybrid networks with black appearance, which enabled the broaden solar absorption, excellent photothermal conversion and fast water diffusion of the photothermal membranes. Driven by sunlight illumination, the photothermal membranes are capable to achieve evaporation rate of 2.01 kg·m−2·h−1 and solar-to-vapor conversion efficiency of 94.6 %, which competes well with other photothermal membranes. The superposition of TA-PEI/FeII/III coating over open-porous membrane substrates synchronously promoted thermal localization and facilitated water-to-steam generation. The reliable durability and salt resistance of the photothermal membranes are also demonstrated. Furthermore, photothermal membranes enables clean water production from seawater and sewage, demonstrating >99.9 % salt and oil pollutant removal. The universality of the polyphenol-mediated coating strategy offers powerful opportunities to engineer photothermal membranes for water purification application. [Display omitted] •Photothermal membranes with raspberry-like nanostructured coating ware fabricated.•The nanostructured coating is engineered by integrating polyphenol-mediated complexation.•The nanostructured coating greatly promotes solar steam generation.•The photothermal membranes enable solar-driven desalination and water purification.•The universality of the photothermal nanostructured coating is revealed.
ISSN:0011-9164
1873-4464
DOI:10.1016/j.desal.2022.116046