Chaohu Xiao scite author profile

Direct solar desalination with excellent solar photothermal efficiency, lower cost, and extended generator device lifetime is beneficial to increase potable water supplies. To address fundamental challenges in direct solar desalination, herein, we present a new and facile method for the scalable fabrication of the polymer porous foam (VMP) as salt-resistant photothermal materials, which was synthesized through a one-step hydrothermal method using styrene and 1-vinyl-3-ethylimidazolium tetrafluoroborate as monomers and N,N′-methylenebisacrylamide as the cross-linking agent. The as-resulted VMP shows excellent mechanical properties which could have a compression strain of 30%, resulting in its superior processability for practical operation. In addition, by taking advantage of its inherent low density, well-controlled porous structure (porosity is 73.81%), and extremely low thermal conductivity (0.03204 W m–1 K–1), the VMP exhibits an excellent solar evaporation property, and the solar photothermal efficiency can reach more than 88% under 1 kW m–2 irradiation. Moreover, the introduction of ionic liquid moiety (imidazolium tetrafluoroborate) into VMP results in its interesting superhydrophilic wettability, which can accelerate water transportation (wetting in 5s) and resolve the crystalline salt within 1.13 h. In addition, the interconnected macropores of the VMP, as water channels, can replenish the vaporized brine on the surface to prevent salt from adhering. The VMP shows a salt-resistant performance, for example, its solar evaporation efficiency remains nearly unchanged after 6 h duration under 1 sun irradiation. Based on its simple and cost-effective manufacturing process, excellent solar photothermal efficiency, and salt resistance, our VMP may be a promising candidate as photothermal materials for practical desalination from seawater and other wastewater.

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Preparation of lotus-like superhydrophobic fluoropolymer films

Wei

Liu

Tian

et al. 2010

Applied Surface Science

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Enhanced solar steam generation of hydrogel composite with aligned channel and shape memory behavior

Fan

Xiao

et al. 2021

Composites Science and Technology

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Benzotriazole-based conjugated microporous polymers as efficient flame retardants with better thermal insulation properties

et al. 2018

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Ag/polypyrrole co-modified poly(ionic liquid)s hydrogels as efficient solar generators for desalination

Xiao

Liang

Hasi

et al. 2020

Materials Today Energy

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Chaohu Xiao

High-Performance Salt-Rejecting and Cost-Effective Superhydrophilic Porous Monolithic Polymer Foam for Solar Steam Generation

Preparation of lotus-like superhydrophobic fluoropolymer films

Enhanced solar steam generation of hydrogel composite with aligned channel and shape memory behavior

Benzotriazole-based conjugated microporous polymers as efficient flame retardants with better thermal insulation properties

Ag/polypyrrole co-modified poly(ionic liquid)s hydrogels as efficient solar generators for desalination

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