Graphene Functionalization towards Developing Superior Supercapacitors Performance

Supercapacitors [Working Title] Pub Date : 2021-08-09 DOI:10.5772/intechopen.98354

A. Elhamid, H. Shawkey, A. Khalil, I. Azzouz

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Abstract

Graphene is known as the miracle material of the 21st century for the wide band of participating applications and epic properties. Unlike the CVD monolayer graphene, Reduced graphene oxide (RGO) is a commercial form with mass production accessibility via numerous numbers of methods in preparation and reduction terms. Such RGO form showed exceptional combability in supercapacitors (SCs) where RGO is participated to promote flexibility, lifetime and performance. The chapter will illustrate 4 critical milestones of using graphene derivatives for achieving SC’s superior performance. The first is using oxidized graphene (GO) blind with polymer for super dielectric spacer. The other three types are dealing with electrolytic SCs based on RGO. Polyaniline (PANI) was grown on GO for exceptionally stable SCs of 100% retention. Silver decoration of RGO was used for all-solid-state printable device. The solid-state gel electrolyte was developed by adding GO to promote current rating. Finally, laser reduced graphene is presented as a one-step and versatile technique for micropatterning processing. The RGO reduction was demonstrated from a laser GO interaction perspective according to two selected key parameters; wavelength and pulse duration.

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石墨烯功能化开发高性能超级电容器

石墨烯因其广泛的应用范围和惊人的性能被誉为21世纪的奇迹材料。与CVD单层石墨烯不同，还原氧化石墨烯(RGO)是一种商业形式，可以通过多种制备和还原方法进行大规模生产。这种RGO形式在超级电容器(sc)中表现出优异的可战斗性，其中RGO参与了提高灵活性，寿命和性能。本章将说明使用石墨烯衍生物实现SC卓越性能的4个关键里程碑。第一种是用氧化石墨烯(GO)盲剂和聚合物作为超级介电隔离剂。其他三种类型是处理基于RGO的电解SCs。聚苯胺(PANI)在氧化石墨烯上生长，获得了100%保留率的异常稳定的SCs。全固态可打印器件采用RGO的银装饰。通过添加氧化石墨烯提高电流额定值，制备了固态凝胶电解质。最后，激光还原石墨烯是一种一步和通用的微图案处理技术。根据两个选定的关键参数，从激光氧化石墨烯相互作用的角度证明了氧化石墨烯的还原;波长和脉冲持续时间。

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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Supercapacitors [Working Title]

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