Solar‐Driven Drum‐Type Atmospheric Water Harvester Based on Bio‐Based Gels with Fast Adsorption/Desorption Kinetics
Hao Zhou, Li Yan, Dexi Tang, Ting Xu, Lin Dai, Chenyu Li, Wenshuai Chen, Chuanling Si
Abstract
Abstract Sorption‐based atmospheric water harvesting is an attractive technology for exploiting unconventional water sources. A critical challenge is how to facilitate fast and continuous collection of potable water from air. Here, a bio‐based gel (cellulose/alginate/lignin gel, CAL gel), resulting from the integration of a whole biomass‐derived polymer network with lithium chloride is reported. A fast adsorption/desorption kinetics, with a water capture rate of 1.74 kg kg −1 h −1 at 30% relative humidity and a desorption rate of 1.98 kg kg −1 h −1 , is simultaneously realized in one piece of CAL gel, because of its strong hygroscopicity, hydrophilic network, abundant water transport channels, photothermal conversion ability, and ≈200‐µm‐thick self‐supporting bulky structure caused by multicomponent synergy. A solar‐driven, drum‐type, tunable, and portable harvester is designed that can harvest atmospheric water within a brief time. Under outdoor conditions, the harvester with CAL gels operates 36 switches (180°) per day realizes a water yield of 8.96 kg kg gel −1 (18.87 g kg device −1 ). This portable harvester highlights the potential for fast and scalable atmospheric water harvesting in extreme environments.