太阳能驱动的可扩展吸湿凝胶,用于回收被动植物蒸腾作用和土壤蒸发产生的水分

Hao Zou, Xinge Yang, Jingling Zhu, Fan Wang, Ziya Zeng, Chengjie Xiang, Danfeng Huang, Jun Li, Ruzhu Wang
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摘要

面对因人口增长和农业需求而加剧的全球缺水问题,迫切需要提高温室栽培的用水效率。大气集水技术的快速发展为我们提供了解决这一问题的机会。这里报告的是一种新型的、太阳能驱动的、可扩展的吸湿凝胶(TCP-Li),它具有超强的吸水能力(3.38 gwater gsorbent-1)和快速的太阳能热释水能力。作为概念验证应用,我们将这种材料用于蒸腾和蒸发吸附装置(TEAD),利用 TCP-Li 的特性从植物蒸腾和土壤蒸发中有效收集水蒸气。TEAD 采用被动运行方式,夜间吸收相对湿度较高的水分,白天利用自然阳光释放水分用于灌溉。温室实验证实,TEAD 在确保植物正常生长的同时,还能提供额外的灌溉用水(每株 87.1 克,每平方米 1,890.6 克),从而实现平均 44.9% 的节水效果。这项研究提出了一种旨在提高温室栽培用水效率的突破性解决方案,为商业化和大规模农业应用提供了巨大潜力,并为缓解全球水危机和优化现代农业用水做出了重要贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Solar-driven scalable hygroscopic gel for recycling water from passive plant transpiration and soil evaporation
In the face of escalating global water scarcity, intensified by population growth and agricultural demands, there is an urgent need to improve water efficiency in greenhouse cultivation. The rapid development of atmospheric water harvesting technology offers us an opportunity to address this issue. Here a novel, solar-driven, scalable hygroscopic gel, termed TCP-Li, that demonstrates exceptional water uptake capacity (3.38 gwater gsorbent−1) and rapid solar thermal water release was reported. As a proof-of-concept application, we utilize this material in a transpiration and evaporation adsorption device (TEAD), which leverages the properties of TCP-Li to efficiently harvest water vapour from plant transpiration and soil evaporation. TEAD operates passively, absorbing moisture at high relative humidity during the night and releasing water for irrigation during the day using natural sunlight. Greenhouse experiments confirmed the efficacy of TEAD in ensuring normal plant growth while providing additional irrigation water (87.1 g per plant and 1,890.6 g m−2), thereby achieving an average water-saving effect of 44.9%. This study introduces a groundbreaking solution aimed at enhancing water efficiency in greenhouse cultivation, offering substantial potential for commercial and large-scale agricultural applications and significantly contributing to mitigating the global water crisis and optimizing water use in modern agriculture. A considerable portion of human water usage is allocated to agriculture, yet optimizing water resources remains a persistent challenge. A promising solution lies in solar-powered technology integrated with hygroscopic porous gel, which captures water vapour from both plant transpiration and soil evaporation. This approach holds potential to enhance water utilization efficiency within greenhouses.
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