Hybrid MOFs Supercapacitor: A Mini Review

Advanced Materials Research Pub Date : 2023-06-21 DOI:10.4028/p-q47uy2

Kalpana Sharma, T. Gupta, S. Vaijayanthimala, N. R. Yogamalar, V. Adimule

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Abstract

In the world of energy storage devices, Supercapacitors occupy a very unique and pivotal position. Their rapid rate of discharge gives them high power density. They have high reversibility and are robust to a large number of charging and discharging cycles. Sustained research has revealed a certain set of properties and behaviour, that every prospective candidate supercapacitor material must possess. Metal organic frameworks (MOFs) with unique textural properties, excellent specific surface area, tuneable porous structure and distinctively advantageous electrochemical behaviour are prominent candidates for the use in energy storage applications. However pristine MOF based materials are handicapped due to their low conductivity and poor mechanical stability. These inherent deficiencies can be overcome by hybridizing pristine MOFs with other materials like carbon materials (Activated Carbon, Graphene and Carbon Nano Tubes), conducting polymers, metals, and small molecules through variety of methods. This review puts the spotlight on the utilization, growth and various forms of hybrid materials based on MOFs for supercapacitor applications. It also highlights the various surface engineering techniques on the materials for high potential applications.

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混合mof超级电容器:迷你回顾

在储能器件领域，超级电容器占据着非常独特和关键的地位。它们的快速放电速率使它们具有高功率密度。它们具有高可逆性和对大量充放电循环的鲁棒性。持续的研究揭示了一套特定的特性和行为，每一个潜在的候选超级电容器材料必须具备。金属有机框架(mof)具有独特的纹理性能、优异的比表面积、可调谐的多孔结构和独特的电化学性能，是储能应用的突出候选者。然而，原始的MOF基材料由于其导电性低和机械稳定性差而受到限制。这些固有的缺陷可以通过将原始mof与其他材料如碳材料(活性炭、石墨烯和碳纳米管)、导电聚合物、金属和小分子通过各种方法杂交来克服。本文综述了基于mof的杂化材料在超级电容器中的应用、生长和各种形式。它还强调了各种表面工程技术对材料的高潜力应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advanced Materials Research

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