氯化锂
盐(化学)
水分
蒸发
锂(药物)
对偶(语法数字)
材料科学
自愈水凝胶
氯化物
化学工程
吸收(声学)
化学
复合材料
无机化学
高分子化学
有机化学
冶金
心理学
热力学
艺术
工程类
文学类
物理
精神科
作者
Jiao He,Qunzhi Zhu,Xin Liu
出处
期刊:Journal of physics
[IOP Publishing]
日期:2025-05-01
卷期号:3018 (1): 012002-012002
标识
DOI:10.1088/1742-6596/3018/1/012002
摘要
Abstract In recent years, hygroscopic hydrogels have gained widespread application in atmospheric water harvesting (AWH) technologies. Sorbent materials, particularly those enabling atmospheric moisture capture, thermal energy storage, and passive cooling, represent promising candidates to address critical challenges associated with global water scarcity and energy transition. However, the large-scale deployment of such systems remains hindered by the reliance on unsustainable and costly sorbent materials. In this study, an innovative dual-network PSCL hydrogel was fabricated through a crosslinking-assisted vacuum freeze-drying methodology. This hydrogel demonstrates exceptional humidity regulation capabilities, achieving nocturnal atmospheric moisture adsorption followed by efficient solar-driven desorption during daylight. Systematic evaluations reveal that the PSCL hydrogel exhibits superior moisture adsorption and desorption capabilities across varying humidity levels. Remarkably, the hydrogel maintained structural integrity and performance stability over 12 consecutive adsorption-desorption cycles, demonstrating its potential for practical implementation in scalable atmospheric water harvesting systems. The integration of tailored porosity and photothermal responsiveness within the dual-network architecture provides a robust platform for optimizing water sorption kinetics and solar energy utilization efficiency. This work advances the development of sustainable hydrogel-based sorbents, offering a viable pathway to overcome the limitations of conventional materials in energy-efficient atmospheric water generation.
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