电离能在能量收集和应用中的应用:从早期发展到当前最先进技术的历程

IF 10.7 Q1 CHEMISTRY, PHYSICAL
EcoMat Pub Date : 2023-08-29 DOI:10.1002/eom2.12408
Won Hyung Lee, Junwoo Park, Sun Geun Yoon, Huding Jin, Junghyup Han, Youn Sang Kim
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引用次数: 1

摘要

离子伏电是能量转换领域的一个突破性概念,它利用水的运动和离子动力学来产生电能。这种现象是基于固体-液体界面的纳米级离子行为与半导体电极中的电子流动之间的相互作用。Ionovoltaic研究旨在通过对固液界面现象的更深入理解,为备受争议的水运动能量转换原理提供最合理和令人信服的机制,并通过开发诸如新型能量收集器,界面分析工具和生物/化学传感器等使能技术来讨论改变相关领域的潜力。此外,开发由小水滴驱动的高效离子光伏装置的努力表明,它对绿色能源系统的进步有潜在的贡献,可以补充太阳能和风能发电,解决环境污染和能源短缺问题。这篇综述文章探讨了利用水运动的能量收集技术的发展,特别关注了作为新兴领域的离子伏特。通过建立基本原理,本研究探讨了固液界面、半导体特性和自然水运动驱动的离子伏打现象,并强调了对复杂离子/界面现象的广泛研究可以在各种工业领域中具有实际应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Ionovoltaics in energy harvesting and applications: A journey from early development to current state-of-the-art

Ionovoltaics in energy harvesting and applications: A journey from early development to current state-of-the-art

Ionovoltaics is a breakthrough concept in energy conversion that harnesses water motion with ion dynamics to generate electrical energy. This phenomenon is based on the interaction between the nanoscopic ionic behavior at the solid–liquid interface and the flow of electrons in a semiconductor electrode. Ionovoltaic research aims to present the most rational and convincing mechanism for the much-debated principle of energy conversion by water motion through a deeper understanding of solid–liquid interfacial phenomena and to discuss the potential to transform related fields through the development of enabling technologies such as novel energy harvesters, interfacial analysis tools, and bio/chemical sensors. Furthermore, efforts to develop high-efficiency ionovoltaic device powered by small water droplets indicate a potential contribution to the advancement of green energy systems that complement solar and wind power generation and address environmental pollution and energy shortages. This review paper explores the evolution of energy harvesting technologies using water motion, with a particular focus on ionovoltaics as an emerging field. By establishing the fundamentals, this study investigates solid–liquid interfaces, semiconductor properties, and natural water motion-driven ionovoltaic phenomena and also highlights that extensive research on complex ion/interface phenomena can have practical applications in diverse industrial fields.

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来源期刊
CiteScore
17.30
自引率
0.00%
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