基于半导体光电极的太阳能可充电海水电池研究进展

IF 8.6 2区 化学 Q1 Chemistry
Samaneh Mozaffari, Mohammad Reza Nateghi
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引用次数: 4

摘要

随着世界能源需求的不断增长,使用可再生能源的趋势迅速增长。阳光作为取之不尽的能源,海洋作为地球上最宝贵的财富之一,都是免费的。同时利用这两种能源和物质(阳光和海洋),可以为未来的能源供应提供可持续的解决方案。在各种类型的储能转换系统中,太阳能可充电海水电池(SRSBs)通过接收太阳能来储存海水的化学能,从而满足了这一需求。SRSBs由两个隔间组成:一个封闭隔间包括有机液体电解质中的金属钠阳极,一个开放隔间包含浸入海水中的半导体光电极,两者之间由陶瓷固体电解质膜隔开。在这个复杂的系统中,光电极被阳光照射,电子被激发并通过外部电路到达Na金属阳极。陶瓷固体电解质只从海水中收集钠离子并将其转移到阳极部分,在阳极部分转移的离子被还原为钠金属原子。同时,阴极部分发生析氧反应。这样,电池就被充电了。在充电过程中使用光电极将SRSBs的电压效率显著提高到90%以上,而只有海水隔间(没有光电极)的电池将无法提供令人满意的性能。因此,为了实现非常高的效率,设计一个精确的系统与最好的组件是绝对必要的。本文综述了SRSBs的工作原理,并阐述了关键组分对SRSBs性能和稳定性的影响。本文还详细介绍了半导体光电极在提高SRSBs电压效率方面的作用,并提出了克服SRSBs商业化障碍的策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Recent Advances in Solar Rechargeable Seawater Batteries Based on Semiconductor Photoelectrodes

Recent Advances in Solar Rechargeable Seawater Batteries Based on Semiconductor Photoelectrodes

With the ever-increasing demand for energy in the world, the tendency to use renewable energies has been growing rapidly. Sunlight, as an inexhaustible energy source, and the oceans, as one of the most valuable treasures on Earth, are available for free. Simultaneous exploitation of these two sources of energy and matter (sunlight and oceans) in one configuration can provide a sustainable solution for future energy supply. Among the various types of such energy storage and conversion systems, solar rechargeable seawater batteries (SRSBs) can meet this need by storing the chemical energy of seawater by receiving solar energy. SRSBs consist of two compartments: a closed compartment including a sodium metal anode in an organic liquid electrolyte, and an open compartment containing a semiconductor photoelectrode immersed in seawater, which are separated from each other by a ceramic solid electrolyte membrane. In this complex system, the photoelectrode is irradiated by sunlight, whereby electrons are excited and reach the Na metal anode after passing though the external circuit. The ceramic solid electrolyte harvests only sodium ions from seawater and transfers them to the anodic part, where the transferred ions are reduced to sodium metal atoms. At the same time, an oxygen evolution reaction takes place at the cathodic part. In this way, the battery is charged. The use of a photoelectrode in the charging process significantly increases the voltage efficiency of SRSBs to more than 90%, whereas a cell with only the seawater compartment (without a photoelectrode) will not deliver satisfactory performance. Therefore, to achieve very high efficiencies, designing an accurate system with the best components is absolutely necessary. This review focuses on the working principle of SRSBs, at the same time explaining the effect of key components on the performance and stability of SRSBs. The role of the semiconductor photoelectrode in improving the voltage efficiency of SRSBs is also described in detail, and finally strategies proposed to overcome obstacles to the commercialization of SRSBs are introduced.

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来源期刊
Topics in Current Chemistry
Topics in Current Chemistry 化学-化学综合
CiteScore
11.70
自引率
1.20%
发文量
0
审稿时长
6-12 weeks
期刊介绍: Topics in Current Chemistry provides in-depth analyses and forward-thinking perspectives on the latest advancements in chemical research. This renowned journal encompasses various domains within chemical science and their intersections with biology, medicine, physics, and materials science. Each collection within the journal aims to offer a comprehensive understanding, accessible to both academic and industrial readers, of emerging research in an area that captivates a broader scientific community. In essence, Topics in Current Chemistry illuminates cutting-edge chemical research, fosters interdisciplinary collaboration, and facilitates knowledge-sharing among diverse scientific audiences.
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