Understanding the chemistry of graphene oxide on redox flow lithium-ion batteries with a view to enhancing the battery's high-density storage

IF 1.4 4区工程技术 Q3 ENGINEERING, CHEMICAL

Asia-Pacific Journal of Chemical Engineering Pub Date : 2023-10-19 DOI:10.1002/apj.2995

Edwin U. Onoh, Asumpta C. Nwanya, Nanasaheb M. Shinde, Nnamdi Nwulu, Fabian I. Ezema

{"title":"Understanding the chemistry of graphene oxide on redox flow lithium-ion batteries with a view to enhancing the battery's high-density storage","authors":"Edwin U. Onoh, Asumpta C. Nwanya, Nanasaheb M. Shinde, Nnamdi Nwulu, Fabian I. Ezema","doi":"10.1002/apj.2995","DOIUrl":null,"url":null,"abstract":"<p>The use of graphene oxide (GO) has shown potential in improving the performance of redox flow lithium-ion batteries (RFLIBs). These types of batteries use a liquid electrolyte containing redox-active species to store and release energy. Despite being scalable, RFLIBs face limitations, namely, low energy density of the electrolyte and reduced cycling stability of the electrodes. However, GO's unique properties, such as its high conductivity as well as large surface area, create an attractive option for enhancing the electrochemical properties of both the electrolyte and electrodes in RFLIBs. When used as an electrode, GO improves the kinetic reversibility reactions, leading to increased electrochemical activity towards redox couples. Charge transfer resistances of positive and negative reactions are reduced, leading to increased voltage energy and efficiency of lithium batteries in terms of energy usage. As redox flow batteries made of lithium ions are an established subsystem and a growing research and development field, there is potential to enhance their performance and reduce costs through the use of GO. The objective of this review is to provide an overview of the chemistry of GO as it pertains to RFLIBs use, covering topics such as its surface chemistry, functionalization, and interactions with redox-active species, as well as its potential for enhancing high-density storage of electricity in batteries. Specifically, it will discuss the impact of GO on redox reactions in the electrolyte, including its ability to raise the redox-active species concentration as well as enhance their stability. The review will also examine how GO impacts the electrodes, including its potential to increase their surface area and conductivity and promote cycling stability. Additionally, the review will address the importance of optimizing the quantity and distribution of GO in both the electrolyte and electrodes of RFLIBs.</p>","PeriodicalId":49237,"journal":{"name":"Asia-Pacific Journal of Chemical Engineering","volume":null,"pages":null},"PeriodicalIF":1.4000,"publicationDate":"2023-10-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Asia-Pacific Journal of Chemical Engineering","FirstCategoryId":"5","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/apj.2995","RegionNum":4,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"ENGINEERING, CHEMICAL","Score":null,"Total":0}

引用次数: 0

Abstract

The use of graphene oxide (GO) has shown potential in improving the performance of redox flow lithium-ion batteries (RFLIBs). These types of batteries use a liquid electrolyte containing redox-active species to store and release energy. Despite being scalable, RFLIBs face limitations, namely, low energy density of the electrolyte and reduced cycling stability of the electrodes. However, GO's unique properties, such as its high conductivity as well as large surface area, create an attractive option for enhancing the electrochemical properties of both the electrolyte and electrodes in RFLIBs. When used as an electrode, GO improves the kinetic reversibility reactions, leading to increased electrochemical activity towards redox couples. Charge transfer resistances of positive and negative reactions are reduced, leading to increased voltage energy and efficiency of lithium batteries in terms of energy usage. As redox flow batteries made of lithium ions are an established subsystem and a growing research and development field, there is potential to enhance their performance and reduce costs through the use of GO. The objective of this review is to provide an overview of the chemistry of GO as it pertains to RFLIBs use, covering topics such as its surface chemistry, functionalization, and interactions with redox-active species, as well as its potential for enhancing high-density storage of electricity in batteries. Specifically, it will discuss the impact of GO on redox reactions in the electrolyte, including its ability to raise the redox-active species concentration as well as enhance their stability. The review will also examine how GO impacts the electrodes, including its potential to increase their surface area and conductivity and promote cycling stability. Additionally, the review will address the importance of optimizing the quantity and distribution of GO in both the electrolyte and electrodes of RFLIBs.

查看原文本刊更多论文

了解氧化石墨烯在氧化还原液流锂离子电池上的化学反应，以提高电池的高密度存储能力

氧化石墨烯（GO）的使用已显示出提高氧化还原液流锂离子电池（RFLIBs）性能的潜力。这类电池使用含有氧化还原活性物质的液态电解质来存储和释放能量。尽管 RFLIB 具有可扩展性，但也面临着一些限制，即电解液的能量密度较低，电极的循环稳定性较差。然而，GO 具有高导电性和大表面积等独特性能，为增强 RFLIB 中电解质和电极的电化学性能提供了极具吸引力的选择。在用作电极时，GO 可改善动力学可逆反应，从而提高氧化还原偶的电化学活性。正负反应的电荷转移电阻减小，从而提高了锂电池的电压能量和能量利用效率。锂离子氧化还原液流电池是一个成熟的子系统，也是一个不断发展的研发领域，通过使用 GO 有可能提高其性能并降低成本。本综述旨在概述与锂离子氧化还原液流电池使用相关的 GO 化学性质，涵盖的主题包括 GO 的表面化学性质、功能化、与氧化还原活性物种的相互作用，以及 GO 在提高电池高密度储电量方面的潜力。具体地说，它将讨论 GO 对电解质中氧化还原反应的影响，包括其提高氧化还原活性物种浓度和增强其稳定性的能力。综述还将研究 GO 如何影响电极，包括其增加电极表面积和导电性以及提高循环稳定性的潜力。此外，本综述还将论述在 RFLIB 的电解液和电极中优化 GO 的数量和分布的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Asia-Pacific Journal of Chemical Engineering ENGINEERING, CHEMICAL-

自引率

11.10%

发文量

111

期刊介绍： Asia-Pacific Journal of Chemical Engineering is aimed at capturing current developments and initiatives in chemical engineering related and specialised areas. Publishing six issues each year, the journal showcases innovative technological developments, providing an opportunity for technology transfer and collaboration. Asia-Pacific Journal of Chemical Engineering will focus particular attention on the key areas of: Process Application (separation, polymer, catalysis, nanotechnology, electrochemistry, nuclear technology); Energy and Environmental Technology (materials for energy storage and conversion, coal gasification, gas liquefaction, air pollution control, water treatment, waste utilization and management, nuclear waste remediation); and Biochemical Engineering (including targeted drug delivery applications).