氟磷酸盐及正硅酸盐锂离子电池正极材料研究进展

综述了用于锂离子电池的氟磷酸盐和正硅酸盐正极材料的研究现状, 重点对各种材料的结构及合成方法与性能的关系, 特别是对如何改善材料的电化学性能进行了总结和探讨. 展望了这两类锂离子电池正极材料的发展趋势.     

动力锂离子电池正极材料磷酸钒锂制备方法

锂离子电池新型正极材料的开发是当前的研究热点,其中磷酸盐材料以其结构稳定、安全性能好及资源丰富等优点备受关注。磷酸钒锂理论能量密度可达500mWh/g,具有较高的电子离子导电性、理论充放电容量及充放电电压平台,被认为是一种极具竞争优势和应用前景的动力锂离子电池正极材料。传统磷酸钒锂合成方法有固相合成法、碳热还原法、溶胶凝胶法和水热合成法等,近年来,又出现了湿法固相配位法、微波固相合成法和流变相法等新型合成方法。本文简要介绍了磷酸钒锂的结构和性能特点,对磷酸钒锂制备方法的最新研究进展进行了较为全面的阐述,并详细介绍了本研究团队近年来在磷酸钒锂材料新型合成方法方面的探索成果。同时对各种合成方法的制备工艺及材料性能进行了对比分析,并探讨了当前存在的问题及未来的研究方向。     

聚阴离子型锂离子电池正极材料研究进展

综述了各种聚阴离子型锂离子电池正极材料的研究现状,重点对各种材料的结构和性能的关系,尤其是聚阴离子在正极材料中的作用,以及改善材料电导率的各种方法及其机理进行了总结和探讨.     

锂离子电池纳米正极材料

综述了锂离子电池纳米正极材料的研究进展,阐述了这种材料用于锂离子电池的优势和存在的问题,把纳米正极材料分为过渡金属嵌锂化合物、金属氧化物和金属硫化物和其它纳米正极材料。归纳了不同纳米正极材料的主要制备方法,探讨了材料的制备方法与其结构、形貌和电化学性能之间的关系,展望了纳米正极材料用于锂离子电池的未来前景。     

废旧锂离子电池正极材料资源化回收与再生

随着电子设备的普及和电动汽车行业的迅速崛起,作为提供能量来源的锂离子电池发挥着重要的作用。以钴酸锂、磷酸铁锂以及三元正极材料为代表的锂离子电池产销量不断增加;与此同时,为了提供更长的续航时间以及续航稳定性,新型锂离子电池材料的研究工作也在不断推进。在此背景下,锂离子电池正极材料的失效、废弃以及资源化回收再生的过程就显得愈发重要,如何在下游解决报废锂离子电池处理的问题也逐渐提上日程。基于此,本文分别从湿法和火法再生两个角度对废旧锂离子电池正极材料的回收和再生过程进行了介绍,包括回收条件优化的方法、较为新颖的回收再生方法以及再生材料的性能等,并总结了回收再生过程的杂质元素,包括铝、铜等元素对再生材料结构和性能的影响以及工业上常用的回收废旧锂离子电池的方法和环境影响。最后对锂离子电池回收的方法进行总结并进行展望。     

钠离子电池磷酸盐正极材料研究进展

近年来,钠离子电池因其原材料丰富、资源成本低廉及安全环保等突出优点,在电化学规模储能领域和低速电动车中具有广阔的应用前景。聚阴离子型磷酸盐具有稳定的框架结构、合适的工作电压和快速的离子扩散路径等特征,是一类极具研究价值和应用前景的钠离子电池正极材料。但是,磷酸盐正极材料电子导电性差和比能量偏低等缺陷限制了其走向实际应用。研究工作者通过体相结构调控和微纳结构设计等手段进行改性研究,旨在提升磷酸盐正极材料的性能表现、推动钠离子储能体系的研究开发。本文综述了钠离子电池磷酸盐正极材料的最新进展,包括正磷酸盐、焦磷酸盐、氟磷酸盐和混合磷酸盐化合物,通过对磷酸盐材料的晶体结构、储钠机理和改性策略等方面的综述,揭示材料成分、结构与电化学性能之间的本征关系,为聚阴离子磷酸盐正极材料的持续改性和新型磷酸盐高压正极材料的探索开发提供指导。     

锂离子电池用新型MV3O8（M=Li+,Na+,NH4+）嵌锂材料

本文详细综述了近年来国内外关于锂离子电池三钒酸盐嵌锂电极材料的研究进展,重点对钒酸锂、钒酸钠和钒酸铵材料的晶体结构、充放电机制、合成及电化学性能研究等进行了介绍,并结合我们课题组的研究情况,对比分析了上述三种材料的优劣。钒酸锂是目前研究的热点,近年来随着新型制备工艺的引入以及包括掺杂包覆改性手段的应用,材料的循环性能得到明显改善,但是相对较差的结构属性限制了其进一步的研究与应用;钒酸钠有较稳定的层状结构,体现了优秀的循环稳定性能和倍率性能,在高功率长寿命有机电解液锂电池正极材料以及水溶液锂电池负极材料的应用中有广阔的前景;相比于钒酸锂,钒酸铵材料具有合成方法更简单、比容量相当、循环性能更优越的特点,分子内氢键的存在使得层状结构更加稳定,该材料有望成为钒系材料中新的研究热点。     

新型高效绿色能源:锂离子电池

锂离子电池又称"摇椅电池",是一种新型高效绿色二次电池,其原理为电池中锂离子在正负极间来回脱出和嵌入,这与普通二次电池不同.其基本构成材料为正极材料、负极材料、电解质及隔膜,各种材料的性能直接影响锂离子电池的性能.     

锂离子蓄电池正极材料LiNi0.8 Co0.2 O2的制备及其电化学性能

用高温固相反应和氧化还原溶胶凝胶法制备了锂离子电池正极材料LiNi0.8Co0.2O2,并对其进行了电化学性能考察。结果显示,氧化还原溶胶凝胶法制备的锂离子电池正极材料的综合性能较高温固相法好。     

锂离子电池正极材料LiMn2O4的低热固相合成与性能表征

锂离子电池具有比能量高、环境污染小等优点,广泛应用于手提电话、便携式电脑、摄像机等设备中。其正极材料的研究是锂离子电池的研究重点。层状结构的LiCoO2、LiNiO2和尖晶石结构的LiMn2O4是仅有的三种能在3.5V以上电位可嵌入Li的正极材料[1~3]。目前市售的锂离子电池主要采用LiCoO2作正极材料,但由于Co资源缺乏和价格相对昂贵,而锰资源丰富,价格低廉且无毒,对环境友好,因此世界各国都在大力进行以LiMn2O4为正极材料的锂离子电池的实用化研究。LiMn2O4传统的制备方法是高温固相反应合成法[4~7],但由于Mn的变价多,与Li形成贫Li或…     

Advances in the Cathode Materials for Lithium Rechargeable Batteries

The accelerating development of technologies requires a significant energy consumption, and consequently the demand for advanced energy storage devices is increasing at a high rate. In the last two decades, lithium‐ion batteries have been the most robust technology, supplying high energy and power density. Improving cathode materials is one of the ways to satisfy the need for even better batteries. Therefore developing new types of positive electrode materials by increasing cell voltage and capacity with stability is the best way towards the next‐generation Li rechargeable batteries. To achieve this goal, understanding the principles of the materials and recognizing the problems confronting the state‐of‐the‐art cathode materials are essential prerequisites. This Review presents various high‐energy cathode materials which can be used to build next‐generation lithium‐ion batteries. It includes nickel and lithium‐rich layered oxide materials, high voltage spinel oxides, polyanion, cation disordered rock‐salt oxides and conversion materials. Particular emphasis is given to the general reaction and degradation mechanisms during the operation as well as the main challenges and strategies to overcome the drawbacks of these materials.     

层状嵌锂多元过渡金属氧化物的研究

综述了近几年来锂离子电池正极材料层状多元过渡金属氧化物的研究进展,重点讨论了具有协同作用的Ni、Co、Mn三元复合型层状正极材料LiCoxMnyNi1-x-yO2 (0相似文献   

Cathode materials for lithium ion batteries prepared by sol-gel methods

Improving the preparation technology and electrochemical performance of cathode materials for lithium ion batteries is a current major focus of research and development in the areas of materials, power sources and chemistry. Sol-gel methods are promising candidates to prepare cathode materials owing to their evident advantages over traditional methods. In this paper, the latest progress on the preparation of cathode materials such as lithium cobalt oxides, lithium nickel oxides, lithium manganese oxides, vanadium oxides and other compounds by sol-gel methods is reviewed, and further directions are pointed out. The prepared products provide better electrochemical performance, including reversible capacity, cycling behavior and rate capability in comparison with those from traditional solid-state reactions. The main reasons are due to the following several factors: homogeneous mixing at the atomic or molecular level, lower synthesis temperature, shorter heating time, better crystallinity, uniform particle distribution and smaller particle size at the nanometer level. As a result, the structural stability of the cathode materials and lithium intercalation and deintercalation behavior are much improved. These methods can also be used to prepare novel types of cathode materials such as nanowires of LiCoO₂ and nanotubes of V₂O₅, which cannot be easily obtained by traditional methods. With further development and application of sol-gel methods, better and new cathode materials will become available and the advance of lithium ion batteries will be greatly promoted.     

锂离子二次电池锰系正极材料

综述了锂离子二次电池锰系正极材料的研究进展，侧重于阐述尖晶石型及层状锰酸锂的制备、结构与电化学性能之间的关系。     

Electrochemical property: Structure relationships in monoclinic Li(3-y)V2(PO4)3

Monoclinic lithium vanadium phosphate, alpha-Li(3)V(2)(PO(4))(3), is a highly promising material proposed as a cathode for lithium-ion batteries. It possesses both good ion mobility and high lithium capacity because of its ability to reversibly extract all three lithium ions from the lattice. Here, using a combination of neutron diffraction and (7)Li MAS NMR studies, we are able to correlate the structural features in the series of single-phase materials Li(3-y)V(2)(PO(4))(3) with the electrochemical voltage-composition profile. A combination of charge ordering on the vanadium sites and lithium ordering/disordering among lattice sites is responsible for the features in the electrochemical curve, including the observed hysteresis. Importantly, this work highlights the importance of ion-ion interactions in determining phase transitions in these materials.     

Structure Design and Performance of LiNixCoyMn1‐x‐yO2 Cathode Materials for Lithium‐ion Batteries: A Review

Lithium‐ion batteries are now considered to be the technology of choice for future hybrid electric and full electric vehicles to address global warming. One of the challenges for improving the performance of lithium ion batteries to meet increasingly demanding requirements for energy storage is the development of suitable cathode materials. The recent advancement of lithium nickel cobalt manganese oxides are investigated as advanced positive cathode materials for lithium‐ion batteries. This review aims at providing the reader with an understanding of the critical scientific challenges facing the development of LiNi_xCo_yMn_1‐x‐yO₂ materials, the latest developments in crystal structure, synthesis methods, and structure designs to unravel the mechanisms of charge and mass transport processes associated with battery performance, and the outlook for future‐generation batteries that exploit gradient structures materials for significantly improved performance to meet the ever‐increasing demands of emerging technologies.     

Review and prospect of layered lithium nickel manganese oxide as cathode materials for Li-ion batteries

Layered structural lithium metal oxides with rhombohedral α-NaFeO₂ crystal structure have been proven to be particularly suitable for application as cathode materials in lithium-ion batteries. Compared with LiCoO₂, lithium nickel manganese oxides are promising, inexpensive, nontoxic, and have high thermal stability; thus, they are extensively studied as alternative cathode electrode materials to the commercial LiCoO₂ electrode. However, a lot of work needs to be done to reduce cost and extend the effective lifetime. In this paper, the development of the layered lithium nickel manganese oxide cathode materials is reviewed from synthesis method, coating, doping to modification, lithium-rich materials, nanostructured materials, and so on, which can make electrochemical performance better. The prospects of lithium nickel manganese oxides as cathode materials for lithium-ion batteries are also looked forward to.     

High-capacity lithium-rich cathode oxides with multivalent cationic and anionic redox reactions for lithium ion batteries

Lithium-rich cathode oxides with capability to realize multivalent cationic and anionic redox reactions have attracted much attention as promising candidate electrode materials for high energy density lithium ion batteries because of their ultrahigh specific capacity. However, redox reaction mechanisms, especially for the anionic redox reaction of these materials, are still not very clear. Meanwhile, several pivotal challenges associated with the redox reactions mechanisms, such as structural instability and limited cycle life, hinder the practical applications of these high-capacity lithium-rich cathode oxides. Herein, we review the lithium-rich oxides with various crystal structures. The multivalent cationic/anionic redox reaction mechanisms of several representative high capacity lithium-rich cathode oxides are discussed, attempting to understand the origins of the high lithium storage capacities of these materials. In addition, we provide perspectives for the further development of these lithium-rich cathode oxides based on multivalent cationic and anionic redox reactions, focusing on addressing the fundamental problems and promoting their practical applications.     

锂离子电池用富锂层状正极材料

正极材料与负极材料是锂离子电池重要组成部分。目前锂离子电池负极材料比容量通常在300mAh/g以上,而正极材料比容量始终徘徊在150mAh/g。正极材料正在成为锂离子电池性能进一步提升的瓶颈。富锂层状正极材料是一类新型正极材料,其可逆容量在200mAh/g以上,其高容量特性引起人们的广泛关注。这类材料可以用xLi₂MO₃·(1-x)LiM'O₂ (M 为Mn, Ti, Zr之一或任意组合; M'为Mn, Ni, Co之一或任意组合; 0≤x≤1)形式表示。由于其组成与结构的特殊性,这类富锂层状正极材料的充放电机理也不同于其它含锂过渡金属氧化物正极材料。本文介绍富锂层状正极材料的合成、结构与充放电机理,重点介绍近年来通过改性提高其电化学性能方面的研究进展,指出目前富锂材料研究中存在的问题,探讨未来的研究重点。