有机氧化还原液流电池的研究进展

氧化还原液流电池（简称液流电池）是一种正在积极研制开发的新型大容量电化学储能装置,其活性物质是流动的电解质溶液,最显著的特点是规模化蓄电. 在广泛利用可再生能源的呼声高涨形势下,可以预见液流电池将迎来一个快速发展的时期. 氧化还原活性物质是液流电池能源转化的载体,也是液流电池中最核心的部分.传统液流电池利用无机材料作为活性物质,然而,无机材料成本高、毒性、资源有限、形成枝晶和电化学活性低等缺点限制了液流电池的大规模应用. 有机活性物质由于具有成本低、“绿色”、资源丰富、分子能级易于调节和电化学反应快等优点,引起了国内外的广泛关注. 近年来,有机液流电池的性能得到快速提升,一系列有机活性物质相继被开发出来. 本文梳理了近年来有机液流电池的研究进展. 首先简要介绍了液流电池的应用领域和技术特点;然后根据电解液种类的不同,详细讨论了有机活性物质在水系和非水系液流电池的应用情况;最后展望了有机液流电池走向实际应用所面临的挑战和潜在研究方向.     

TEMPO及其衍生物在有机液流电池体系中的应用

氧化还原液流电池是一类循环效率高、性质可调控的拥有广阔前景的储能体系。相比无机液流电池体系,以TEMPO及其衍生物作为氧化还原活性材料的有机液流电池,具有成本较低、电压较高、可逆性好、结构可调等优势。本文综述了以TEMPO及其衍生物作为氧化还原活性材料的有机液流电池的研究进展,介绍了相关的实验方法、提出了未来的研究方向。     

面向规模储能的聚合物微粒“泥浆”电池

<正>随着人类对能源需求的持续提高,太阳能、风能等可再生能源的开发和利用备受关注。可再生能源发电的规模化发展需要与之相匹配的大规模、高效能量存储技术。液流电池是有潜力的大型电化学储能技术之一,具有储能规模大、循环寿命长、安全性高等优势1,2。发展更高储能密度、更低成本、可商业化应用的液流电池技术是实现国家能源安全和可持续发展的重大需求。液流电池的     

石墨基液流电池复合双极板

液流电池是一种安全性高、使用寿命长、可扩展的大规模储能系统,可以协助电网调峰储能,提高能源利用率,发展前景广阔。双极板是液流电池的重要组成部分。功能上起到了分隔、串联电池、传导电流、为电堆提供结构支撑等作用。从成本构成角度看,双极板的价格占电堆成本的比重也较大。开发高性能、低成本的双极板对加快液流电池的商业化应用具有重要意义,也是目前业界的迫切需求。虽然文献上报道了许多针对液流电池双极板开发的工作,但是目前高性能、低成本的液流电池双极板产品仍无法充分满足市场需求。本文着重介绍了石墨基复合双极板的研究现状,介绍了材料选择、工艺流程对关键性能的影响,对相关工作进行了评述,并为液流电池双极板的开发提出了建议。     

低成本-高性能超级电容器有机小分子电极材料的研究进展

超级电容器因为具有快速充放电速率与高功率密度,已经在许多能源储存领域的应用中取得了迅速的发展,其可以在备用电源、军用设备、便携式电子产品以及混合动力汽车等方面作为电池的有效补充。其电极材料的特性是决定电荷存储的最关键因素。与传统的碳材料、过渡金属氧化物、氢氧化物及导电聚合物相比,有机小分子材料具有资源可持续性、环境友好性、潜在的低成本、结构多样性等特点,在低分子量下可实现多电子可逆法拉第反应,为获得高能量密度的超级电容器奠定电化学反应基础。通过共价或非共价功能化的方法将氧化还原活性有机分子固定在导电碳基底上(如石墨烯、碳纳米管、活性炭等),可以方便地将电荷从电活性分子转移到载流元件,提高电化学储能器件的功率能力,使其电化学性能得到有效的发挥。这篇综述总结了近期报道的低成本、高性能有机小分子电极材料,通过有机小分子的共价功能化和非共价功能化,从合成策略和化学修饰等角度进行了介绍,最后对有机小分子电极材料的发展趋势进行了展望。     

高性能水系混合离子电池:不断超越的工作电压

正采用有机电解质的锂离子电池具有3 V以上的宽电化学窗口,因而比水系离子电池具有更高的能量密度。然而,有机电解质易燃、有毒,如果使用不恰当,会带来严重的安全及环境问题,制约了锂离子电池在规模储能中的应用。研究者们一直在试图用水系电解质代替有机电解质。相对而言,水系电解质环境友好和安全,且其离子电导率比有机电解质高两个数量级,有望实现电池的高功率,还避免了有机电解质所需的严格制造条件,大大降低了生产成本。因此,水系离子电     

关于水系锌离子电池中无氧钒基正极材料的综述

水系锌离子电池具有功率密度高、环境友好、安全性高、低成本和锌资源丰富等优点，被认为具有潜力成为下一代电化学储能系统。然而，正极材料较差的电化学性能制约了水系锌离子电池的未来发展。尽管氧化锰、氧化钒、普鲁士蓝类似物、有机材料等多种材料已被广泛研究，设计具有高性能的理想正极材料仍面临着巨大挑战。无氧钒基化合物由于具有高的电导率、大的层间距、低的离子扩散势垒和高的理论比容量，受到越来越多的关注。本文总结了无氧钒基化合物的研究进展，包括电极材料的设计、改善其电化学性能的有效途径以及复杂的储能机制，提出了无氧钒基化合物目前面临的挑战和未来的发展前景，为进一步制备新型高性能钒基正极材料提供指导。     

水系锌离子电池锰基正极材料

水系锌离子电池(AZIBs)以低成本、高安全性和高环保特性在大规模储能领域具有广阔的应用前景,当前备受关注的正极材料是研究的热点。锰基化合物因具有资源丰富、环境友好和价格低廉等优点,是最具市场应用前景的一类正极材料。本文详细综述了不同锰基化合物的结构特点以及锰基AZIBs在充放电过程中涉及的四种储能机理,讨论了AZIBs锰基正极材料目前存在的问题和优化策略。最后,提出了AZIBs锰基正极材料具有研究前景的可能性方向,以期对AZIBs的发展起到一定的预见作用。     

水系锌二次电池MnO2正极的晶体结构、反应机理及其改性策略

水系锌二次电池凭借其安全性高、环境友好、成本低廉、能量密度较高等诸多优势,有望应用于下一代大规模储能系统。电池的发展依赖于电极材料,二氧化锰由于其高丰度、低成本、毒性小等优势,在水系锌二次电池领域得到广泛应用。本文将从二氧化锰的晶体结构、反应机理及电化学性能出发,对其在水系锌二次电池中的研究进展进行系统综述。特别地,针对其容量低、循环稳定性差等问题,本文从储能机理(包括嵌入-脱嵌机制和溶解-沉积机制)角度出发,总结相对应的优化策略,为先进水系锌锰二次电池的设计开发提供参考。     

高电压/宽温域水系碱金属离子电池的研究进展

水系储能器件具有固有的高安全性、环境友好性和成本低的优势，在未来智能电网、便携式/可穿戴电子产品等领域显示出巨大的应用潜力。然而水的热力学分解电压低、冰点高，导致水系电解液电化学稳定电压窗口窄以及凝固点高，极大地限制了水系储能器件的能量密度与宽温域应用。因此，设计耐高电压、抗冻的水系电解液，成为水系储能器件大规模、多场景应用的关键。本文系统综述了高电压/宽温域水系碱金属离子电池电解液设计的研究进展，从热力学和动力学角度出发，分别重点介绍提高电解液电压窗口和工作温度范围的各类策略以及相关作用机制。进一步提出宽温域、高压水系电解液的潜在设计思路，并对高性能水系碱金属离子电池的发展方向进行展望。     

Electrochemical Evaluation of Diketopyrrolopyrrole Derivatives for Nonaqueous Redox Flow Batteries

Redox flow batteries (RFBs) employing nonaqueous electrolytes could potentially operate at much higher cell voltages, and therefore afford higher energy and power densities, than RFBs employing aqueous electrolytes. The development of such high-voltage nonaqueous RFBs requires anolytes that are electrochemically stable, especially in the presence of traces of oxygen and/or moisture. The inherent atmospheric reactivity of anolytes mandates judicious molecular design with high electron affinity and electrochemical stability. In this study, diketopyrrolopyrrole (DPP)-based TDPP-Hex-CN₄ is proposed as a stable redox-active molecule for anolytes in nonaqueous organic RFBs. We demonstrate organic RFBs using TDPP-Hex-CN₄ as anolyte with unisol blue (UB) 1,4-bis(isopropylamino)anthraquinone and 1,4-di-tert-butyl-2,5-bis(2-methoxyethoxy)benzene (DBBB) as catholytes. Cyclic voltammetry measurements with scans repeated over 200 cycles were performed to establish the electrochemical stability of the redox pairs. Symmetric flow-cell studies show that TDPP-Hex-CN₄ exhibits stable capacity up to 700 cycles. Redox flow cells employing TDPP-Hex-CN₄ /UB and TDPP-Hex-CN₄/DBBB as redox pairs demonstrate that DPP derivatives are propitious materials for anolytes in all organic nonaqueous RFBs.     

Recent progress in organic redox flow batteries:Active materials,electrolytes and membranes

Redox flow batteries(RFBs) have great potentials in the future applications of both large scale energy storage and powering the electrical vehicle. Critical challenges including low volumetric energy density,high cost and maintenance greatly impede the wide application of conventional RFBs based on inorganic materials. Redox-active organic molecules have shown promising prospect in the application of RFBs,benefited from their low cost, vast abundance, and high tunability of both potential and solubility. In this review, we discuss the advantages of redox active organic materials over their inorganic compart and the recent progress of organic based aqueous and non-aqueous RFBs. Design considerations in active materials, choice of electrolytes and membrane selection in both aqueous and non-aqueous RFBs are discussed.Finally, we discuss remaining critical challenges and suggest future directions for improving organic based RFBs.     

有机硫化合物在锂硫电池中的应用

锂硫电池具有理论能量密度高、环境友好和成本低等优点,有望成为替代锂离子电池的新一代储能系统。然而,锂硫电池充放电产物的绝缘性、可溶性多硫化锂的穿梭效应、硫正极体积膨胀及锂枝晶的不可控生长,严重影响了锂硫电池的实际容量发挥和循环稳定性。为解决上述问题,采用有机硫化合物来替代单质硫作为正极材料是有前途的策略。调控有机硫化合物的硫链、碳链及其相互作用,可改变其电化学反应过程,提高离子/电子电导,抑制穿梭效应。有机硫化合物作为电解液添加剂,可调控硫正极的反应过程并保护金属锂负极,作为聚合物电解质的改性链段可加速锂离子传导。本综述对有机硫化合物在锂硫电池的正极、电解液添加剂和固态电解质中的应用研究进展进行详细的阐述。将有机硫化合物的结构、反应机理和电化学性质联系起来,为解决锂硫电池存在的问题提供见解。最后,提出高性能有机硫化合物的设计合成和机理研究思路,以期实现可实用化的锂硫电池。     

氟代溶剂在锂金属电池中的应用

近年来，锂金属电池由于具有较高的能量密度而成为储能领域的研究热点。电解液作为锂金属电池的“血液”发挥着至关重要的作用。在传统锂离子电池电解液中，锂金属负极与电解液之间的界面副反应严重并伴随着锂枝晶生长，从而导致安全隐患以及循环寿命缩短等问题。在解决锂金属负极问题上，电解液调控策略具有易操作性和有效性，因而在推动锂金属电池发展方面具有举足轻重的地位。氟代电解液是目前重要的研究方向，氟代电解液在循环过程中能够在电极表面形成富含LiF的固体电解质界面膜(SEI)；该界面膜不仅可以有效抑制负极锂枝晶的形成，并且在正极方面能够大幅提高电解液的氧化稳定性，从而提升高电压正极的适配性和锂金属电池的循环稳定性。氟代电解液中氟代溶剂/氟代锂盐的分子结构对电解液的溶剂化结构有重要影响。当氟代溶剂分子中氟原子的位置与数量不同时，氟代溶剂的物理化学性质也会随之发生变化，进而改变了电解液与电极的界面反应性。因此，氟代溶剂能够起到调制SEI膜成分和结构的作用，是决定电池性能的关键因素。本文总结了应用于锂金属电池的主要氟代溶剂，尤其是近几年来发展的新型氟代溶剂；着重介绍了高度氟代的溶剂分子作为局域超浓电解液的稀释剂，以及对溶剂进行精准分子设计得到的部分氟代溶剂等。此外，本文还分析探讨了氟代溶剂分子与电池性能之间的构效关系，展望了构建新型氟代溶剂分子的策略，希望能对电解液溶剂分子的结构设计以及构效关系的评估有一定的启发意义。     

氟代溶剂在锂金属电池中的应用

Lithium metal batteries, which use lithium metal as the anode, have attracted tremendous research interest in recent years, owing to their high energy density and potential for future energy storage applications. Despite their advantages such as high energy density, the safety concerns and short lifespan significantly impede their practical applications in transportation and electronic devices. Tremendous efforts have been devoted to overcoming these problems, including materials design, interface modification, and electrolyte engineering. Among these strategies, electrolyte regulation plays a key role in improving the efficiency, stability, and safety of lithium metal anodes. As an important class of electrolyte components, fluorinated solvents, which can decompose to form LiF-rich interphase layers on both anode and cathode, have been proven to enhance the stability of lithium metal anodes and improve the oxidative stability of the electrolytes. Meanwhile, the spatial structure of fluorinated solvents, such as the number and sites of fluorine atoms, can influence the physicochemical properties of the electrolytes and the compositions/structure of the solid-electrolyte interphase, which eventually dictates the cycling performance of Li metal batteries. Recently, many fluorinated solvents with different molecular structures have been designed to regulate the solvation structure of electrolytes, and these solvents exhibit novel electrochemical properties in lithium metal batteries. However, there are few comprehensive reviews that summarize the fluorinated solvents used in Li metal batteries and discuss their functions in electrolytes and their physicochemical properties. This review summarizes the novel fluorinated solvents used in lithium metal batteries in recent years, which have been classified into three parts: diluents, traditional solvents, and novel molecules, based on their functions in the electrolytes. In every part, the understanding of the interactions between fluorinated solvents and Li ions, the decomposition mechanism of fluorinated solvents at the interface of the electrode, the functions of fluorinated solvents in the electrolytes, and the structure-activity relationship between the fluorinated solvents and battery performance have been comprehensively summarized and discussed. Moreover, the advantages and disadvantages of fluorinated solvents have been discussed, and the importance of precisely controlling the number of fluorine atoms and the structure of fluorinated solvents has been emphasized. At the end of this review, a perspective for designing new fluorinated solvents has been proposed. We believe that this review can provide insights on designing novel fluorinated solvents for high-performance Li metal batteries.      

Recent Development of Electrolytes for Aqueous Organic Redox Flow Batteries (Aorfbs): Current Status,Challenges, and Prospects

In recent years, aqueous organic redox flow batteries (AORFBs) have attracted considerable attention due to advancements in grid-level energy storage capacity research. These batteries offer remarkable benefits, including outstanding capacity retention, excellent cell performance, high energy density, and cost-effectiveness. The organic electrolytes in AORFBs exhibit adjustable redox potentials and tunable solubilities in water. Previously, various types of organic electrolytes, such as quinones, organometallic complexes, viologens, redox-active polymers, and organic salts, were extensively investigated for their electrochemical performance and stability. This study presents an overview of recently published novel organic electrolytes for AORFBs in acidic, alkaline, and neutral environments. Furthermore, it delves into the current status, challenges, and prospects of AORFBs, highlighting different strategies to overcome these challenges, with special emphasis placed on their design, composition, functionalities, and cost. A brief techno-economic analysis of various aqueous RFBs is also outlined, considering their potential scalability and integration with renewable energy systems.     

A Sustainable Redox-Flow Battery with an Aluminum-Based,Deep-Eutectic-Solvent Anolyte

Nonaqueous redox-flow batteries are an emerging energy storage technology for grid storage systems, but the development of anolytes has lagged far behind that of catholytes due to the major limitations of the redox species, which exhibit relatively low solubility and inadequate redox potentials. Herein, an aluminum-based deep-eutectic-solvent is investigated as an anolyte for redox-flow batteries. The aluminum-based deep-eutectic solvent demonstrated a significantly enhanced concentration of circa 3.2 m in the anolyte and a relatively low redox potential of 2.2 V vs. Li⁺/Li. The electrochemical measurements highlight that a reversible volumetric capacity of 145 Ah L⁻¹ and an energy density of 189 Wh L⁻¹ or 165 Wh kg⁻¹ have been achieved when coupled with a I₃⁻/I⁻ catholyte. The prototype cell has also been extended to the use of a Br₂-based catholyte, exhibiting a higher cell voltage with a theoretical energy density of over 200 Wh L⁻¹. The synergy of highly abundant, dendrite-free, multi-electron-reaction aluminum anodes and environmentally benign deep-eutectic-solvent anolytes reveals great potential towards cost-effective, sustainable redox-flow batteries.     

A Sustainable Redox‐Flow Battery with an Aluminum‐Based,Deep‐Eutectic‐Solvent Anolyte

Nonaqueous redox‐flow batteries are an emerging energy storage technology for grid storage systems, but the development of anolytes has lagged far behind that of catholytes due to the major limitations of the redox species, which exhibit relatively low solubility and inadequate redox potentials. Herein, an aluminum‐based deep‐eutectic‐solvent is investigated as an anolyte for redox‐flow batteries. The aluminum‐based deep‐eutectic solvent demonstrated a significantly enhanced concentration of circa 3.2 m in the anolyte and a relatively low redox potential of 2.2 V vs. Li⁺/Li. The electrochemical measurements highlight that a reversible volumetric capacity of 145 Ah L⁻¹ and an energy density of 189 Wh L⁻¹ or 165 Wh kg⁻¹ have been achieved when coupled with a I₃⁻/I⁻ catholyte. The prototype cell has also been extended to the use of a Br₂‐based catholyte, exhibiting a higher cell voltage with a theoretical energy density of over 200 Wh L⁻¹. The synergy of highly abundant, dendrite‐free, multi‐electron‐reaction aluminum anodes and environmentally benign deep‐eutectic‐solvent anolytes reveals great potential towards cost‐effective, sustainable redox‐flow batteries.     

锂硫银锗矿固态电解质研究进展

全固态电池因其较高的安全性和能量密度而成为下一代电动汽车和智能电网用储能器件的重点研究方向之一。开发具有高室温锂离子电导率、化学/电化学稳定性优异、对电极材料兼容性优异等特点的固态电解质材料是推动全固态电池发展的重要研究课题之一。硫化物电解质因其相对较高的室温电导率(~10⁻³ S∙cm⁻¹)、较低的电解质/电极固-固界面阻抗等优点而在众多无机固体电解质材料中成为研究热点。本文基于作者多年研究成果和当前国内外发表的相关工作,从电解质的结构、离子传导、合成、综合性能改善及在全固态电池中的应用等方面系统总结了锂硫银锗矿固态电解质材料研究,并分析了该类电解质面临的问题和挑战,最后探讨了其未来可能的研究方向和发展趋势。