Fabrication of CB/Ni3S2 micro-nanostructure decorated foam with Janus wettability towards solar-driven interfacial evaporation

The ever-increasing population and environmental pollution have led to a global crisis of freshwater scarcity. Solar-driven interfacial evaporation, as an eco-friendly and cost-effective solution, holds great promise to address this issue. In this work, the solvothermal reaction and spray coating we...

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Published inJournal of environmental chemical engineering Vol. 13; no. 2; p. 115619
Main Authors Yin, Xiaoli, Yin, Tianyu, Li, Peiyuan, Yu, Sirong, Lu, Zehang
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.04.2025
Subjects
Hydrophilicity
Interfacial evaporation
Photothermal effect
Superhydrophobicity
Photothermal effect
Hydrophilicity
Superhydrophobicity
Interfacial evaporation
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Abstract The ever-increasing population and environmental pollution have led to a global crisis of freshwater scarcity. Solar-driven interfacial evaporation, as an eco-friendly and cost-effective solution, holds great promise to address this issue. In this work, the solvothermal reaction and spray coating were adopted to fabricate Janus Carbon black-Polydimethylsiloxane-Heazlewoodite-Nickel foam (CB-PDMS-Ni3S2-NF), a material that integrated asymmetric wettability and intense solar absorption property for efficient interfacial evaporation. CB-PDMS-Ni3S2-NF displayed superhydrophobicity on one side and hydrophilicity on the other. When exposed to solar irradiation, the surface temperature would rise sharply. Eventually, CB-PDMS-Ni3S2-NF presented an evaporation rate of 1.47 kg·m−2·h−1 and evaporation efficiency of 92.05 %, respectively, under 1-sun irradiation. In addition, it could maintain a high evaporation rate even when floating in solutions containing 5 M sodium chloride (NaCl) or methylene blue. Importantly, the stable CB-PDMS-Ni3S2-NF was able to endure multiple mechanical tests and effective against the accumulation of salt or contaminants. Moreover, it could be manipulated and recycled easily owing to its fast magnetic responsiveness. This work is believed that provides a promising material for efficient interfacial evaporation. •A foam exhibiting Janus wettability and intense solar absorption is presented.•The foam as an interfacial evaporator shows high evaporation rate and efficiency.•The foam can endure multiple mechanical tests and resist the salt accumulation.•The foam can be easily manipulated and recycled with the aid of magnetic field.
AbstractList The ever-increasing population and environmental pollution have led to a global crisis of freshwater scarcity. Solar-driven interfacial evaporation, as an eco-friendly and cost-effective solution, holds great promise to address this issue. In this work, the solvothermal reaction and spray coating were adopted to fabricate Janus Carbon black-Polydimethylsiloxane-Heazlewoodite-Nickel foam (CB-PDMS-Ni3S2-NF), a material that integrated asymmetric wettability and intense solar absorption property for efficient interfacial evaporation. CB-PDMS-Ni3S2-NF displayed superhydrophobicity on one side and hydrophilicity on the other. When exposed to solar irradiation, the surface temperature would rise sharply. Eventually, CB-PDMS-Ni3S2-NF presented an evaporation rate of 1.47 kg·m−2·h−1 and evaporation efficiency of 92.05 %, respectively, under 1-sun irradiation. In addition, it could maintain a high evaporation rate even when floating in solutions containing 5 M sodium chloride (NaCl) or methylene blue. Importantly, the stable CB-PDMS-Ni3S2-NF was able to endure multiple mechanical tests and effective against the accumulation of salt or contaminants. Moreover, it could be manipulated and recycled easily owing to its fast magnetic responsiveness. This work is believed that provides a promising material for efficient interfacial evaporation. •A foam exhibiting Janus wettability and intense solar absorption is presented.•The foam as an interfacial evaporator shows high evaporation rate and efficiency.•The foam can endure multiple mechanical tests and resist the salt accumulation.•The foam can be easily manipulated and recycled with the aid of magnetic field.
ArticleNumber 115619
Author Yin, Tianyu
Lu, Zehang
Yin, Xiaoli
Li, Peiyuan
Yu, Sirong
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Snippet The ever-increasing population and environmental pollution have led to a global crisis of freshwater scarcity. Solar-driven interfacial evaporation, as an...
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SubjectTerms Hydrophilicity
Interfacial evaporation
Photothermal effect
Superhydrophobicity
Title Fabrication of CB/Ni3S2 micro-nanostructure decorated foam with Janus wettability towards solar-driven interfacial evaporation
URI https://dx.doi.org/10.1016/j.jece.2025.115619
Volume 13
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