Release time:2023-10-22  Hits:

• Indexed by:Journal paper
• First Author:Ran Niu
• Correspondence Author:Jiang Gong,Jiakang Min
• Co-author:Jiaxin Ren,J. Justin Koh,Ling Chen,Jinping Qu,Xiaodong Xu,Jalal Azadmanjiri
• Journal:Advanced Energy Materials
• Included Journals:SCI、EI
• Discipline:Engineering
• First-Level Discipline:Material Science and Engineering
• Document Type:J
• Date of Publication:2023-10-16
• Impact Factor:27.8
• Abstract:The integration of solar-driven interfacial evaporation and electricity co-generation is considered a promising approach to simultaneously alleviate freshwater scarcity and the energy crisis. However, affected by intermittent solar irradiation/uncontrollable weather, the overall performance of solar-driven evaporation in the real world is greatly reduced. Herein, inspired by antifreeze proteins in beetles that survive in extreme climates, all-weather solar-driven interfacial evaporators with a sandwich structure are designed. The top and bottom layers composed of MnO2-modified cotton cloth are used for photothermal conversion and water transport, meanwhile, the middle layer made of a phase change microcapsule/hydrogel composite serves for heat storage and release. Under 1 kW m−2 irradiation, the evaporator exhibits a high evaporation rate of 2.67 kg m−2 h−1 and an efficiency of 89.5%. In the dark, the heat released from the phase change layer supports an evaporation rate of 0.43 kg m−2 h−1, 3.6 times that of pure water. Additionally, assembled with a thermoelectric module, the hybrid device achieves a stable output electricity power of 0.42 W m−2 under 1-sun illumination and a prolonged output for 30 min in the dark. This work provides a novel approach for full-time solar-powered steam-electricity co-generation and a proof of concept for biomimetic steam generation/heat management integration.
• Links to published journals:https://onlinelibrary.wiley.com/doi/10.1002/aenm.202302451