The Prospective Applications of arising Nanostructured Dielectric Materials in Storage of Energy: A Comprehensive Review

Q3 Engineering
Suryakanta Swain, H. B. Samal, Santosh Satpathy, B. R. Jena, G. Pattnaik, Sheerin Bashas, Sonu Barad
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引用次数: 0

Abstract

The manufacture and study of innovative materials that enable the availability of relevant technologies are vital in light of the energy demands of various human activities and the need for a substantial shift in the energy matrix. A strategy based on the creation of enhanced applications for batteries has been devised to reduce the conversion, storage, and feeding of renewable energy like fuel cells and electrochemical capacitors. Conductive polymers (CP) can be utilised instead of traditional inorganic chemicals. Electrochemical energy storage devices with similar capabilities can be built using approaches based on the production of composite materials and nanostructures. CP's nanostructuring is notable for its concentration on synergistic coupling with other materials, which sets it apart from other nanostructures that have been developed in the preceding two decades. This is due to the fact that, when paired with other materials, their distinctive morphology and adaptability significantly enhance performance in areas like the suppression of ionic diffusion trajectories, electronic transport and the improvement of ion penetrability and intercalation spaces. The present study forecasts the wide-ranging modern applications of diverse nanostructured dielectric materials along with its future prospectives. The potential contributions of nanostructured carbon nanotubes to the development of innovative materials for energy storage devices are also critically discussed in this context, which delivers a summary of the present state of information on this emerging topic.
纳米结构介电材料在储能领域的应用前景:全面综述
鉴于人类各种活动对能源的需求,以及能源结构发生重大转变的需要,制造和研究能够提供相关技术的创新材料至关重要。导电聚合物(CP)可被用来替代传统的无机化学品。使用基于生产复合材料和纳米结构的方法,可以制造出具有类似功能的电化学储能装置。CP 的纳米结构因其专注于与其他材料的协同耦合而引人注目,这使其有别于前二十年开发的其他纳米结构。这是因为,当与其他材料配对时,其独特的形态和适应性可显著提高其在抑制离子扩散轨迹、电子传输以及改善离子穿透性和插层空间等方面的性能。本研究预测了多种纳米结构介电材料的广泛现代应用及其未来前景。本研究预测了多种纳米结构电介质材料的广泛现代应用及其未来前景,并对纳米结构碳纳米管在开发用于储能设备的创新材料方面的潜在贡献进行了批判性讨论,对这一新兴课题的信息现状进行了总结。
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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来源期刊
Micro and Nanosystems
Micro and Nanosystems Engineering-Building and Construction
CiteScore
1.60
自引率
0.00%
发文量
50
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