Recent advances and research progress on the role of carbon-based biomass in ultra-capacitors: A systematic review

Energy Storage Pub Date : 2024-06-19 DOI:10.1002/est2.646
Dhinesh Balasubramanian, Hariharan Varadharajan, Inbanaathan Papla Venugopal, Edwin Geo Varuvel
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Abstract

Biomass-derived carbon material has drawn significant attention recently due to its wide availability, environmentally free, and effective performance of the resulting porous carbons for supercapacitor (SC) applications. Carbon electrode material derived from biomass is used for energy storage (ES) because it has distinct qualities in porosity, a large specific surface area, and excellent conductivity. Furthermore, these materials' homogeneous, flawless biological structures can be used as models to create electrode materials with accurate geometries. The ES devices, known as SCs, also known as ultra-capacitors, serve as a link between a capacitor and a battery. Due to their charge storage, SCs can produce a much higher density than batteries. Several factors, including the electrode's potential window, the electrode materials characteristics, and the electrolyte choice, have a major effect on SC performance. Therefore, all efforts have been made to develop SC electrode materials. This paper explains the different types of SCs and how they work. The various available biomass resources, as well as the methods for producing them, are outlined. In addition, the different types of electrode materials, activation methods, heteroatom functionalization, and electrolyte types are all thoroughly examined. The application and research advancement of biomass-derived carbon used in SCs over the past 3 years are highlighted. Furthermore, this research outlines the benefits of SCs for the environment and the economy, as well as present challenges and future recommendations for advancing biomass-derived carbon applications. This article aims to give an in-depth knowledge of carbon-based biomass materials that are used in SCs.

关于碳基生物质在超级电容器中的作用的最新进展和研究进展:系统综述
生物质衍生碳材料因其广泛的可获得性、对环境的无害性以及所产生的多孔碳在超级电容器(SC)应用中的有效性能,最近引起了人们的极大关注。从生物质中提取的碳电极材料可用于储能(ES),因为它具有独特的多孔性、大比表面积和优异的导电性。此外,这些材料均匀、无暇的生物结构可用作模型,制造出具有精确几何形状的电极材料。这种 ES 设备被称为 SC,也被称为超级电容器,是电容器和电池之间的纽带。由于具有电荷存储功能,SC 可以产生比电池高得多的密度。电极电位窗口、电极材料特性和电解液选择等因素对 SC 性能有重大影响。因此,人们一直在努力开发 SC 电极材料。本文介绍了不同类型的 SC 及其工作原理。本文概述了各种可用的生物质资源及其生产方法。此外,还对不同类型的电极材料、活化方法、杂原子官能化和电解质类型进行了深入探讨。重点介绍了生物质衍生碳在过去 3 年中在 SC 中的应用和研究进展。此外,本研究还概述了气相沉积物对环境和经济的益处,以及在推进生物质衍生碳应用方面所面临的挑战和未来建议。本文旨在深入介绍 SC 中使用的碳基生物质材料。
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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CiteScore
2.90
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