朝向高度拒盐的太阳界面蒸发:光热材料选择、结构设计和能量管理

Jiang Wang, Shuai Guo, Swee Ching Tan, Zechang Wei
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摘要

随着工业的发展,水污染和水资源短缺已成为严重的全球性问题。由于地球上的海水储量丰富,太阳能驱动的高效蒸发是缓解淡水短缺的一种很有前途的方法。太阳能蒸发技术因其在海水淡化和污水处理领域的潜在应用前景而备受关注。此外,通过设计太阳能吸收器和结构,可以提高太阳能驱动的蒸发效率。到目前为止,人们已经探索了许多实现高太阳能驱动蒸发效率的策略,主要包括光热转换材料的选择和结构优化。本文综述了太阳能吸收器、结构设计和能量管理是实现高性能太阳能驱动蒸发系统的关键。本文报道了基于不同光热转换机制、衬底结构设计和能量管理方法的四种太阳能吸收器,以实现高转换效率。我们还系统地研究了海水淡化中可用的拒盐策略。本文综述了高效太阳能蒸发系统的发展现状,并对光热转换材料、结构设计和能源管理等方面进行了综述。最后,对海水淡化中除盐技术的发展前景进行了展望。
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Towards highly salt-rejecting solar interfacial evaporation: Photothermal materials selection, structural designs, and energy management

With the development of the industry, water pollution and shortage have become serious global problems. Owing to the abundance of seawater storage on earth, efficient solar-driven evaporation is a promising approach to relieve the freshwater shortage. The solar-driven evaporation has attracted tremendous attention due to its potential application in the seawater desalination and wastewater treatment fields. Also, the solar-driven evaporation efficiency can be enhanced by designing both solar absorbers and structures. Up to now, many strategies have been explored to achieve high solar-driven evaporation efficiency, mainly including the selection of photothermal conversion materials and structure optimization. In this review, the solar absorbers, structural designs, and energy management are proposed as the keys for high performance solar-driven evaporation systems. We report four kinds of solar absorbers based on different photothermal conversion mechanisms, substrate structure designs, and energy management methods for the purpose to achieve high conversion efficiency. And we also systematically investigate the available salt-rejections strategies for seawater desalination. This review aims to summarize the current development of efficient solar-driven evaporation systems and provide insights into the photothermal conversion materials, structural designs, and energy management. Finally, we propose the perspectives of the salt-rejection technologies for seawater desalination.

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