Bridging materials innovations to sorption-based atmospheric water harvesting devices

IF 79.8 1区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Nature Reviews Materials Pub Date : 2024-04-30 DOI:10.1038/s41578-024-00665-2
Yang Zhong, Lenan Zhang, Xiangyu Li, Bachir El Fil, Carlos D. Díaz-Marín, Adela Chenyang Li, Xinyue Liu, Alina LaPotin, Evelyn N. Wang
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Abstract

The atmosphere contains 13,000 trillion litres of water, and it is a natural resource available anywhere. Sorption-based atmospheric water harvesting (SAWH) is capable of extracting water vapour using sorbent materials across a broad spectrum of relative humidity, opening new avenues to address water scarcity faced by two-thirds of the population of the world. Although substantial progress has been made, there is still a considerable barrier between fundamental research and real-world applications. In this Review, we provide a multiscale perspective for SAWH technologies that can fill existing knowledge gaps across multiple length scales. First, we elucidate water sorption mechanisms at the molecular level, approaches to understanding sorbent materials, and water transport phenomena. With microscopic insights, we bridge materials innovations to device realization, discuss strategies to enhance device-level sorption kinetics and heat transfer performance, and show that a multiscale design and optimization strategy can lead to a new opportunity space towards system thermodynamic limits. Finally, we provide an outlook for the technoeconomic, social and environmental impact of large-scale SAWH as a global water technology. By bridging materials to devices, we envision that this multiscale perspective can guide next-generation SAWH technologies and facilitate a broader impact on society and the environment. Harvesting freshwater from the air using water sorption materials is an innovative strategy to address water scarcity. This Review offers a multiscale perspective to design the next generation of sorption-based atmospheric water harvesting technology by bridging materials innovations to device realization and provides practical guidelines to understand its real-world impact.

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将材料创新与基于吸附原理的大气集水装置相结合
大气中含有 13,000 万亿升水,是随处可得的自然资源。基于吸附技术的大气水收集(SAWH)能够利用吸附材料在广泛的相对湿度范围内提取水蒸气,为解决全球三分之二人口面临的缺水问题开辟了新途径。虽然已经取得了长足的进步,但基础研究与实际应用之间仍存在相当大的障碍。在本综述中,我们将从多尺度的视角来探讨 SAWH 技术,以填补多个长度尺度上的现有知识空白。首先,我们阐明了分子水平的吸水机制、了解吸水材料的方法以及水传输现象。通过微观洞察,我们将材料创新与器件实现联系起来,讨论了增强器件级吸附动力学和传热性能的策略,并表明多尺度设计和优化策略可以为系统热力学极限带来新的机遇空间。最后,我们展望了大规模 SAWH 作为全球水技术所带来的技术经济、社会和环境影响。从材料到设备,我们设想这种多尺度视角可以指导下一代 SAWH 技术,并促进对社会和环境产生更广泛的影响。
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来源期刊
Nature Reviews Materials
Nature Reviews Materials Materials Science-Biomaterials
CiteScore
119.40
自引率
0.40%
发文量
107
期刊介绍: Nature Reviews Materials is an online-only journal that is published weekly. It covers a wide range of scientific disciplines within materials science. The journal includes Reviews, Perspectives, and Comments. Nature Reviews Materials focuses on various aspects of materials science, including the making, measuring, modelling, and manufacturing of materials. It examines the entire process of materials science, from laboratory discovery to the development of functional devices.
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