锂离子电池纳米电极材料研究

采用ＸＲＤ，ＴＥＭ方法对纳米相电极材料的结构，形貌进行表征，并用循环伏安法，恒流充放电法对电极材料的嵌锂电化学行为进行研究。结果表明，由于纳米材料的微结构特性使萁 具有优越的嵌锂特性；１）锂离子嵌入电极材料内部的深度小，过程短，具 较大的比表面，有利于采用较大的电流对该电池进行充放电；２）具有较大的嵌锂空间位置，有利于增加电极的锂嵌容量。     

中空碳材料用于钠离子电池负极的研究进展

实现钠离子电池等储能设备的大规模应用对于能源的可持续发展以及完成“碳达峰碳中和”目标具有重要意义.开发高性能的负极材料可提升钠离子电池的能量密度和循环稳定性,是实现钠离子电池大规模应用的关键性因素.中空碳材料因其独特的结构而具有优异的倍率性能与循环稳定性,作为钠离子负极材料具有广阔的应用前景.本文从多角度出发,综合评述了中空碳材料的合成方法,以及其形貌、杂原子修饰策略与储钠性能之间的关系,并对其未来发展方向进行了展望.     

模板法制备无机氧化物中空微球的研究进展

总结了模板法在制备无机氧化物中空微球方面的应用,主要从模板的种类和壳层增长机理两方面进行阐述,并对无机氧化物中空微球的应用及发展前景作了简要介绍。     

中空磁性金属微纳米材料的特性及应用研究进展

中空磁性金属微纳米材料因其具有超大比表面积,生物相容性及优异的电、光、化学和磁特性,在国防民生、催化、能源环境、生物医学等领域广泛应用。结合国内外研究现状,就中空磁性金属微纳米材料的吸波性能、催化特性、电化学特性、生物相容性和磁特性及其应用等方面的研究进展、尚存问题和未来发展趋势展开述评。     

模板法制备孔状锂离子电池电极材料*

模板法为孔状锂离子电池材料的制备开辟了一条新的途径,近几年已经成为材料制备领域研究的热点之一。本文介绍了模板法在制备孔状锂离子电池材料上的新进展,阐述了模板法的原理、分类以及制备过程。最后总结了孔状锂离子电池材料的特点和目前存在的问题,并展望了该领域的发展趋势。     

摇椅锂离子二次电池及其嵌入式电极材料

本文着重对摇椅锂离子二次电池的工作原理，电池采用的嵌入式电极材料的结构，常见的合成方法，插层反应和电化学性能的研究情况以及应用前景和存在的问题等作一综述。     

锂离子电池纳米材料研究

报道了作者最近在锂离子电池纳米材料方面的研究工作 .包括纳米负极材料 (如Sb ,SnSb ,CuSn及Si) ,纳米正极材料 (如CuS)合成 ,电化学性质 ,以及纳米材料的晶体结构与形貌在充放电过程中的变化等研究 .此外还报道了具有纳米尺度阴离子的锂盐在聚合物电解质中的增塑作用以及纳米硅Raman光谱和光致发光谱受电化学锂掺杂的影响 .最后对纳米材料的本征性质与其电化学性质的关系进行了讨论 ,并对其在锂离子电池中的应用及在基础研究方面的意义给予了评述 .     

模板法制备无机纳米材料的研究进展

模板法在无机纳米材料的制备过程中能够有效地控制形貌、粒径和结构,已成为合成无机纳米材料的前沿方法。综述了模板法制备无机纳米材料的研究进展,主要介绍了硬模板剂(多孔阳极氧化铝、介孔碳)和软模板剂(高分子聚合物、生物高分子)的制备及其应用,结合模板法的作用机制,重点论述了不同种类的模板剂在无机纳米材料制备过程中对于形貌的影响。并对模板法制备无机纳米材料的前景和现存问题进行了总结。参考文献35篇。     

无机全固态锂离子电池界面性能研究进展

固体电解质不存在易燃等安全问题, 发展固态锂电池技术是解决液体电解质锂电池安全问题的根本途径. 随着社会对大体积锂离子电池需求的增长以及人们对电池的安全性关注度的日益提高, 发展固态锂离子电池已迫在眉睫. 制备性能良好的全固态锂电池的关键在于获得高室温离子导电率的固体电解质以及在电极与电解质之间形成良好的接触面. 大量的研究集中在制备高室温导电率的固体电解质, 目前已经制备出能与液体电解质相媲美的高室温导电率的固体电解质, 但固态锂电池的高倍率性能仍然较差, 原因是在电极与固体电解质的界面处具有较高的阻抗. 关于固态锂电池电极与电解质界面的研究文章相对较少. 本文简要介绍了一些具有高室温导电率的氧化物及硫化物电解质, 着重分析了全固态锂电池电极与电解质界面处具有高阻抗的原因以及减少界面阻抗的界面改性方法.     

中空磁性金属微纳米材料种类及合成方法的研究进展

中空磁性金属微纳米材料在国防民生、新型能源、环境修复、生物医学等诸多领域应用广泛,高效合成性能优异的该材料一直是材料化学的研究热点。综述了中空磁性金属微纳米材料的种类及合成方法的研究进展,为进一步研发和优化该材料提供参考。     

Nanomaterials for rechargeable lithium batteries

Energy storage is more important today than at any time in human history. Future generations of rechargeable lithium batteries are required to power portable electronic devices (cellphones, laptop computers etc.), store electricity from renewable sources, and as a vital component in new hybrid electric vehicles. To achieve the increase in energy and power density essential to meet the future challenges of energy storage, new materials chemistry, and especially new nanomaterials chemistry, is essential. We must find ways of synthesizing new nanomaterials with new properties or combinations of properties, for use as electrodes and electrolytes in lithium batteries. Herein we review some of the recent scientific advances in nanomaterials, and especially in nanostructured materials, for rechargeable lithium-ion batteries.     

微波法合成锂离子材料LiCoO2的研究

以氧化钴和氢氧化锂为原料,采用微波技术合成锂离子电池正极材料LiCoO2.主要考查的微波合成条件有反应时间、输出功率与反应温度.采用XRD、SEM方法和电化学测试手段研究了产物的结构与性能.研究结果表明微波合成法可以制备层状结构、电化学性能稳定的LiCoO2材料.在充放电实验中,电池的首次放电容量达到140 mAh·g-1.与传统的合成方法相比,微波合成技术具有节省能源、提高效率和环境友好的特点.     

Template-free fabrication of porous CuCo2O4 hollow spheres and their application in lithium ion batteries

Journal of Solid State Electrochemistry - In this study, we develop a simple template-free strategy to fabricate uniform porous CuCo2O4 hollow spheres. The shells of the as-synthesized CuCo2O4...     

Vanadium oxide gels as electrode materials for lithium batteries

Electrochemical lithium insertion has been studied in a large number of vanadium oxides with three dimensional framework structure. Several of these oxides have shown high capacities for lithium insertion and good reversibility.Pure solutions of decavanadic acid have shown to undergo spontaneous polycondensation reaction forming sols or gels of highly polymerized vanadium oxides, M _w 10⁶. After dehydration a series of xerogels with varying amounts of water, V₂O₅ · nH₂O, can be obtained. The structure of these xerogels consists of ribbons of corner and edge sharing VO₆ octahedra stabilized by interlayer water molecules. Under ambient conditions the water content corresponds to n=1.8, but this value can be reversibly changed under mild drying conditions.This report deals with the electrochemical insertion of lithium in dried vanadium oxide xerogels, with special regard to the use of these materials as electrodes in rechargeable lithium batteries.     

The development of lithium ion secondary batteries

Lithium ion secondary batteries (LIBs) were successfully developed as battery systems with high volumetric and gravimetric energy densities, which were inherited from lithium secondary batteries (LSBs) with metallic lithium anodes. LSBs have several drawbacks, however, including poor cyclability and quick-charge rejection. The cell reaction in LIB is merely a topochemical one, namely the migration of lithium ions between positive and negative electroces. No chemical changes were observed in the two electrodes or in the electrolytes. This results in little chemical transformation of the active electrode materials and electrolytes, and thus, LIBs can overcome the weaknesses of LSBs; for example, LIBs show excellent cyclability and quick-charge acceptance. Many difficulties, however, were encountered during the course of development, including capacity fade during cycling and safety issues. This article is the story of the development of LIBs and it describes how the difficulties were surmounted.     

The recent advances in constructing designed electrode in lithium metal batteries

In this review, we focus on the design of lithium electrode and its recent advancements, which suppress the growth of lithium dendrites and improve the performance of the rechargeable batteries. To suppress the growth of lithium dendrites, the general design rules of the system require a uniform lithium ion flux, a low current density, a homogeneous nucleation process and a stable SEI layer. Improvements of the battery performance have been achieved through the delicate design of lithium electrode and here they are summarized into three groups:i) optimizing the 3D porous nanostructure of the current collector, ii) constructing rational host for lithium metal and prelithiating the 3D host matrix with molten lithium, iii) protecting the surface of lithium metal by functional layers. An outlook of the challenges and the potentials of lithium metal battery is also provided, which will facilitate the future development of lithium metal battery.     

Nano-structured phosphorus composite as high-capacity anode materials for lithium batteries

More than LiP service: The adsorption of red phosphorus into porous carbon provides a composite anode material for lithium-ion batteries. The amorphous nano phosphorus, in the carbon matrix, shows highly reversible lithium storage with high coulombic efficiencies and stable cycling capacity of 750?mAh per gram composite.     

高产率/低成本制备一维纳米结构负极材料及其在锂离子电池中的应用

锂离子电池的性能在很大程度上由其电极材料决定.目前,商用的锂离子电池负极材料主要为石墨,其性能并不能满足下一代大容量/高功率锂电池的需求.尽管科研工作者在新型锂离子电池负极材料方面做了大量的研究,但距离其大规模应用仍然有诸多问题需要解决,其中最重要的问题之一为实现其高产率/低成本的规模化制备.本文重点介绍了本课题组在一维纳米结构负极材料规模化制备方面取得的进展,包括一维多孔三氧化二铁/四氧化三钴、一维多孔草酸盐和一维多孔铁酸锌.