Energy storage in the 21st century: A comprehensive review on factors enhancing the next-generation supercapacitor mechanisms

Divya Meena, Rinku Kumar, Saurabh Gupta, Obeidullah Khan, Deepak Gupta, Milan Singh
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Abstract

Supercapacitors are promising candidates for energy storage devices with longer cycle life and higher power density. The development of next-generation supercapacitors relies on a profound understanding of the underlying mechanisms that boost their performance. This comprehensive review critically examines the factors influencing the next-generation supercapacitor mechanisms. It covers the fundamental principles of supercapacitors, including their unique charge storage mechanisms, such as electrical double layer and pseudo-capacitance. It investigates various materials and techniques viz. electrode morphology, the utilisation of advanced electrode materials, and surface modifications for enhancing specific capacitance. Furthermore, it delves into the critical role of electrolytes in supercapacitors' performance. It also assesses the influence of different electrolytes on capacitance, voltage window, and cycling stability. The effect of electroconductivity on the enhanced performance of supercapacitors is also investigated. Additionally, the review covers the in-depth significance of externally applied magnetic fields on supercapacitor systems. Research on factors enhancing the capacitance is crucial for producing next-generation supercapacitors with greater efficiency. The vitality of this research lies in improving energy storage devices, transport electrification, stabilizing electrical grids, powering portable electronic devices, and reducing intermittency issues. Moreover, the enhanced capacitance of supercapacitors can reduce reliance on fossil fuels, contributing to a more sustainable energy storage solution.
21世纪的储能:下一代超级电容器机制增强因素综述
超级电容器具有更长的循环寿命和更高的功率密度,是储能器件的理想选择。下一代超级电容器的发展依赖于对提高其性能的潜在机制的深刻理解。本文综合评述了影响下一代超级电容器机制的因素。它涵盖了超级电容器的基本原理,包括其独特的电荷存储机制,如电双层和伪电容。它研究了各种材料和技术,即电极形态,先进电极材料的利用,以及提高比电容的表面修饰。此外,它还深入研究了电解质在超级电容器性能中的关键作用。还评估了不同电解质对电容、电压窗和循环稳定性的影响。研究了电导率对超级电容器性能增强的影响。此外,综述了外外加磁场对超级电容器系统的深入意义。研究提高电容的因素对于生产效率更高的下一代超级电容器至关重要。本研究的生命力在于改进储能装置、运输电气化、稳定电网、为便携式电子设备供电、减少间歇性问题。此外,超级电容器的增强电容可以减少对化石燃料的依赖,有助于实现更可持续的能源存储解决方案。
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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