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Ion‐Transfer Engineering via Janus Hydrogels Enables Ultrahigh Performance and Salt‐Resistant Solar Desalination

Nan He, Yongfang Yang, Haonan Wang, Fan Li, Bo Jiang, Dawei Tang, Lin Li

2023Advanced Materials116 citationsDOI

Abstract

Abstract Emerging solar interfacial evaporation offers the most promising response to the severe freshwater crisis. However, the most challenging bottleneck is the conflict between resisting salt accumulation and maintaining high evaporation performance since conventional salt‐resistant evaporators enhance water flow to remove salt, leading to tremendous heat loss. Herein, an ion‐transfer engineering is proposed via a Janus ion‐selective hydrogel that enables ion‐electromigration salt removal, breaking the historical dependence on water convection, and significantly lowering the heat loss. The hydrogels drive cations downward and anions upward, away from the evaporation surfaces. An electrical potential is thus established inside the evaporator and salt in 15 wt% brine is removed stably for seven days. A record‐high evaporation rate of 6.86 kg m −2 h −1 in 15 wt% brine, 2.5 times the previously reported works, is achieved. With the from‐scratch salt‐resistant route, comprehensive water‐thermal analysis, and record‐high performance, this work holds great potential for the future salt‐resistant evaporators.

Topics & Concepts

Materials scienceDesalinationBrineEvaporatorEvaporationJanusSolar desalinationChemical engineeringSalt (chemistry)Mass transferIonNanotechnologyChemistryMechanical engineeringThermodynamicsMembraneOrganic chemistryChromatographyBiochemistryPhysicsHeat exchangerEngineeringSolar-Powered Water Purification MethodsSolar Thermal and Photovoltaic SystemsMembrane Separation Technologies
Ion‐Transfer Engineering via Janus Hydrogels Enables Ultrahigh Performance and Salt‐Resistant Solar Desalination | Litcius