锂钛复合氧化物锂离子电池负极材料的研究

采用 3种化学方法合成锂钛复合氧化物 .应用X -射线衍射分析对其结构进行表征以及电化学性能测试 ,结果表明 :由Li2 CO3、TiO2 高温合成的锂钛复合氧化物为尖晶石结构的Li4Ti5 O12 .Li4Ti5 O12 电极在 1 .5V左右有一放电平台 ,充放电可逆性良好 ,即充电电压平台与此接近 ,且电极的比容量较大 ,循环性能良好 .以 0 .30mA·cm- 2 充放电时 ,首次放电容量可达 30 0mAh·g- 1,可逆比容量为 1 0 0mAh·g- 1,经多次充放电循环后 ,其结构仍保持稳定性 .试验电池测试表明 ,Li4Ti5 O12 可选作Li4Ti5 O12 /LiCoO2 锂离子电池的负极材料 .     

二维纳米片组成的花状铁醇盐及其微纳结构三氧化二铁衍生物的储锂性能

Fe₂O₃作为锂电池负极材料具有诸多优点,但其较低的本征电导率和充放电循环过程中材料粉化使得其电化学储锂性能有待改善。 本文以具有花状微纳结构的铁醇盐为反应中间体,在空气气氛下烧结制备出具有花状微纳结构的铁基负极材料Fe₂O₃。 纳米花状的铁醇盐可以在低烧结温度下转化为目标产物,从而使得产物能够保持中间体的形貌。 300 ℃热处理条件下,所得样品在电流密度为200 mA/g时首次放电比容量为1360 mA·h/g,循环100次后的容量仍然达到515.6 mA·h/g;相比之下,450和800 ℃热处理所得样品100次循环后,比容量分别为247.6和206.7 mA·h/g。 微纳结构在增加材料的活性的同时,也能够抑制材料的粉化现象,因而所制得的材料表现出较大的比容量和良好的循环性能,为解决Fe₂O₃负极材料循环性能差的问题提供了思路。     

锂离子电池负极碳材料的表面改性与修饰Ⅰ．表面的氧化、还原处理对碳材料电极性能的影响

通过各种氧化／还原体系对碳材料进行表面氧化、还原处理,研究了碳材料表面的痕量有机含氧官能团对以碳材料作为锂离子电池负极的电池性能的影响．结果表明,碳材料表面大量有机含氧官能团的存在将引起电池性能的严重恶化;相应地如对电极表面进行一定的还原处理、以减少碳表面有机官能团的含量及其氧化程度则可提高电极（碳材料）的容量及首次循环效率．文中还结合碳材料表面有机官能团对电解液溶剂的分解反应以及碳电极表面钝化膜形成的影响进行了解释．     

Core–Shell Carbon‐Coated CuO Nanocomposites: A Highly Stable Electrode Material for Supercapacitors and Lithium‐Ion Batteries

Herein we present a simple method for fabricating core–shell mesostructured CuO@C nanocomposites by utilizing humic acid (HA) as a biomass carbon source. The electrochemical performances of CuO@C nanocomposites were evaluated as an electrode material for supercapacitors and lithium‐ion batteries. CuO@C exhibits an excellent capacitance of 207.2 F g^?1 at a current density of 1 A g^?1 within a potential window of 0–0.46 V in 6 M KOH solution. Significantly, CuO electrode materials achieve remarkable capacitance retentions of approximately 205.8 F g^?1 after 1000 cycles of charge/discharge testing. The CuO@C was further applied as an anode material for lithium‐ion batteries, and a high initial capacity of 1143.7 mA h g^?1 was achieved at a current density of 0.1 C. This work provides a facile and general approach to synthesize carbon‐based materials for application in large‐scale energy‐storage systems.     

基于不同前驱体制备的硬碳负极材料的储锂性能

以聚丙烯腈、石油沥青和花生壳为前驱体,在1200℃下碳化制备三种不同的硬碳材料。通过扫描电子显微、X射线衍射、氮气吸附/脱附测试和拉曼光谱等方法探究不同前驱体所制备的硬碳材料的表面形貌和物相结构。通过恒流充放电测试考察了这三种硬碳负极材料的电化学性能。结果表明,花生壳基硬碳的初始放电比容量最高,但首圈库仑效率最低,石油沥青基硬碳的首圈库仑效率最高但是比容量最低,聚丙烯腈基硬碳具有较高的循环比容量和稳定性。     

二硫化钦作为锉离子电池负极材料的特性

采用固相法合成了纯六方相的TiS₂粉体. X射线衍射(XRD)、扫描电子显微镜(SEM)结果表明该材料具有特征层状结构, 其颗粒大小在10-20 μm之间. 作为锂离子电池负极材料, TiS₂在3.00 V(vs. Li⁺/Li)以下有3个明显的放电平台, 首次可逆容量达668 mAh·g^-1, 在第一个放电电压范围(3.00-1.40 V)内具有优异的循环可逆性. 深度放电时由于Li₂S的生成和材料颗粒严重破碎, 在低于0.50 V时材料的循环性能不佳. 通过减小材料颗粒度和提高导电剂含量, TiS₂的电化学性能得到显著改善.     

LiNi0.8Co0.2-XMXO2的合成和电化学性能研究

锂离子电池手机、笔记本电脑、电动汽车技术、医疗仪器电源以及宇宙空间等领域。目前商品化锂离子电池正极活性材料主要是LiCoO2、LiNiO2、LiMn2O4,及其掺杂化合物。LiNiO2具有比容量高,功率大、价格适中等优点,但也存在合成困难,热稳定性差等问题,其实用化进程一直比较缓慢。     

脉冲激光沉积法制备SnSe薄膜电极及其电化学性质

采用脉冲激光溅射Sn和Se粉末的混合靶制备SnSe薄膜, XRD结果显示室温下得到的是Sn和Se的混合薄膜, 当基片温度为200 ℃时, 薄膜主要由晶态的SnSe组成. 该薄膜的首次放电容量为498 mAh•g-1, 30次循环之后的放电容量为260 mAh•g-1. 充放电测试、循环伏安曲线和ex-situ XRD结果显示, SnSe能够和Li发生可逆的电化学反应, 充电过程中能够重新生成SnSe, 表现出不同于其它氧族元素锡化物的电化学性质.     

锂离子电池锂锰氧化物高压嵌锂材料的结构和电化学性能研究

利 用 Ｘ Ｒ Ｄ、 Ｉ Ｃ Ｐ、 Ｔ Ｇ Ａ 、 Ｄ Ｔ Ａ 及 恒 流 充 放 电 等 方 法 研 究 分 析 了 一 种 特 殊 天 然 结 构 Ｍｎ Ｏ２（ Ｎ Ｍ Ｄ） 材料的结 构、组成 以及电 化学嵌锂 特性． Ｘ Ｒ Ｄ 分析 表明,该样 品材料 是由钠水 锰矿以及水羟 锰矿复 合结构组 成的 Ｍｎ Ｏ２ 纳米 纤 维． 充放 电 循环 结果 显 示,其 前 期循 环容 量 可高 达 １５０ｍ Ａｈ／ ｇ 左 右,但性 能尚不够 稳定． 本文采 用一种 水热法高 压嵌锂处 理,可将 Ｎ Ｍ Ｄ 样品 转变为 具有３ ×３ 大隧道结 构的钡 镁锰矿（ Ｔｏｄｏｒｏｋｉｔｅ） 型锂 锰氧 化 物,既 增 强了 Ｌｉ ＋ 嵌 入 隧道 或 层间 结 构 的循环稳定 性． 并 显著提 高锂锰氧 化物电 极材料性 能的 稳定 性,以 充放 电电 流密 度 为０ ．８ ｍ Ａ／ｃ ｍ ２ ,经过１８０ 次 循环后 其比容量 仍具有 １１０ ｍ Ａｈ／ ｇ ． 该类 大隧道结 构锂锰 氧化物可 作为一 种３ Ｖ 的锂离子电极 材料．     

Facile synthesis of hollow Ti_2Nb_(10)O_(29) microspheres for high-rate anode of Li-ion batteries

Titanium niobium oxides emerge as promising anode materials with potential for applications in lithium ion batteries with high safety and high energy density.However,the innate low electronic conductivity of such a composite oxide seriously limits its practical capacity,which becomes a serious concern especially when a high rate charge/discharge capability is expected.Here,using a modified template-assisted synthesis protocol,which features an in-situ entrapment of both titanium and niobium species during the formation of polymeric microsphere followed by a pyrolysis process,we succeed in preparing hollow microspheres of titanium niobium oxide with high efficiency in structural control.When used as an anode material,the structurally-controlled hollow sample delivers high reversible capacity(103.7 m A h g~(-1)at 50 C)and extraordinary cycling capability especially at high charge/discharge currents(164.7 m A h g~(-1)after 500 cycles at 10 C).     

Preparation and electrochemical properties of Ag-modified TiO2 nanotube anode material for lithium–ion battery

TiO₂ nanotubes prepared by using a hydrothermal process were firstly coated with silver nanoparticles as the anode materials for lithium–ion batteries by the traditional silver mirror reaction. The physical properties of the as-synthesized samples were investigated by X-ray diffraction and transmission electron microscopic. The as-prepared samples were used as negative materials for lithium–ion battery, whose charge–discharge properties, cyclic voltammetry, electrochemical impedance spectroscopy and cycle performance were examined in detail. The results showed that the Ag additive decreased the polarization of anode, and marvelously improved the high-rate discharge capacity and cycling stability of TiO₂ nanotubes.     

Controlled synthesis of hierarchically-structured MnCo_2O_4 and its potential as a high performance anode material

To satisfy the upsurging demand for energy storage in modern society,anode materials which can deliver high capacity have been intensively researched for the next generation lithium ion batteries.Typically,the binary MnCo_2O_4 with a characteristic coupled metal cations showed promising potential due to its high theoretical capacity and low cost.Here,by means of a well-designed synthesis control,we demonstrated a scalable process to achieve a hierarchical structure of MnCo_2O_4,which existed as uniform microspheres with embedded mesopores,showing favorable structural characters for high performance during a fast charge/discharge process.Our synthesis highlighted the importance of sodium salicylate as an essential additive to control the precipitation of the two involved metal cations.It was proved that a dual role was played sodium salicylate which cannot only facilitate the formation of microspheric shape,but also act as an effective precursor for the creation of inner mesopores.We confirmed that the hierarchically-structured MnCo_2O_4 showed outstanding performance when it was tested as an anode material in lithium ion batteries as revealed by its extraordinary cycling stability and high rate capability.     

SnNi-deposited carbonaceous mesophase spherule as anode material for lithium ion batteries

Carbonaceous mesophase spherule (CMS) is a commercial anode material for rechargeable lithium batteries. A composite anode material of SnNi deposited carbonaceous mesophase spherule was prepared by co-precipitation method. The structural and electrochemical characterization of the SnNi/CMS composite anode material was studied. According to the measurement of its electrochemical characterization, the prepared SnNi/CMS composite anode material shows much better electrochemical performance than CMS. The first discharge capacity of 360 mA h g⁻¹ was obtained for the SnNi/CMS composite anode material, and its discharge capacity maintained at 320–340 mA h g⁻¹ in the following cycles. It indicates that the modification of CMS with SnNi alloy can further improve the intercalation performance of CMS. SnNi/CMS composite material shows a good candidate anode material for the commercial rechargeable lithium batteries.     

以LiCoO2为阴极的全固态薄膜锂电池的研究

Amorphous and oriented polycrystalline LiCoO2 thin films, used as cathode material for an all-solid-state thin film battery, were fabricated by using RF magnetron sputtering and annealed at different temperatures. The morphology and structure of LiCoO2 thin films were characterized by scanning electron microscopy and X-ray diffraction. All-solid-state thin film batteries, comprised of LiCoO2 cathode films with different structures, lithium phosphorous oxynitride electrolyte film and metallic lithium anode film, was successfully prepared and their properties were examined by chronopotentiometry. Results showed that the structure and crystallinity of the LiCoO2 films strongly influenced the electrochemical performance of all-solid-state thin film lithium batteries. Worth nothing was the battery with an oriented polycrystalline LiCoO2 film it exhibited the best electrochemical performance, and delivered a discharge capacity of ～55.4 μAh/cm2μm. Furthermore, when subjected to over 450 charge/discharge cycles, that battery suffered no obvious fode in capacity.     

Soft carbon-coated bulk graphite for improved potassium ion storage

Potassium-ion batteries (PIBs) have attracted tremendous attention for large-scale energy storage fields based on abundant potassium resources. Graphite is a promising anode material for PIBs due to its low potassium ion intercalation voltage and mature industrialized preparation technology. However, the inability of graphitic structures to endure large volume change during charge/discharge cycles is a major limitation in their advancement for practical PIBs. Herein, a soft carbon-coated bulk graphite composite is synthesized using PTCDA as a carbon precursor. The PTCDA-derived soft carbon coating layer with large interlayer distance facilities fast potassium ion intercalation/extraction in the BG@C composite and buffers severe volume change during the charge/discharge cycles. When tested as anode for PIBs, the composite realizes enhanced rate capability (131.3 mAh/g at 2 C, 1 C = 279 mA/g) and cycling performance (capacity retention of 76.1% after 150 cycles at 0.5 C). In general, the surface modification route to engineer graphite anode could inherently improve the electrochemical performance without any structural alteration.     

Pyrene‐Anderson‐Modified CNTs as Anode Materials for Lithium‐Ion Batteries

An organo‐functionalized polyoxometalate (POM)–pyrene hybrid (Py‐Anderson) has been used for noncovalent functionalization of carbon nanotubes (CNTs) to give a Py‐Anderson‐CNT nanocomposite through π–π interactions. The as‐synthesized nanocomposite was used as the anode material for lithium‐ion batteries, and shows higher discharge capacities and better rate capacity and cycling stability than the individual components. When the current density was 0.5 mA cm^?2, the nanocomposite exhibited an initial discharge capacity of 1898.5 mA h g^?1 and a high discharge capacity of 665.3 mA h g^?1 for up to 100 cycles. AC impedance spectroscopy provides insight into the electrochemical properties and the charge‐transfer mechanism of the Py‐Anderson‐CNTs electrode.     

First investigation on charge-discharge reaction mechanism of aqueous lithium ion batteries: a new anode material of Ag2V4O11 nanobelts

Aqueous lithium ion batteries have been widely considered as promising "green" batteries due to several advantages, such as low toxicity, low cost, high safety, as well as high ion conductivity. But unlike the great effort devoted to understanding the lithium insertion/extraction process in non-aqueous lithium ion batteries, the knowledge about this in aqueous electrolytes is still lacking research at present. In this work, taking a new anode material of single-crystalline Ag(2)V(4)O(11) nanobelts as an example, we investigated the charge-discharge reaction mechanism of aqueous lithium ion batteries for the first time. A two-step reaction mechanism was proposed and it was also deduced that crystallinity loss of the electrode materials and partial irreversibility of silver oxidation are the key reasons for rapid capacity fading. We expect this work to provide a scientific platform that could help to investigate and evaluate other electrode materials in this research area.     

锂离子电池用富锂正极材料的研究进展

富锂材料xLi₂MnO₃·(1-x)LiMO₂（0-1）和低廉的价格已引起人们的广泛兴趣. 但其首次充放电循环的较大不可逆容量损失、较差的倍率性能和循环过程的材料相变等关键问题制约了其发展. 富锂材料结构解析和充放电机理探索一直是研究的热点. 目前,富锂材料是否为固溶体仍有争论,首次充电4.5 V平台的氧流失机理已得到确认. 为了提高富锂材料的电化学性能,可从体相掺杂、表面包覆和结构形貌控制等方面对材料进行改性,其电化学性能有显著提升. 本文综述了富锂材料最新研究进展,归纳了相关制备方法,重点介绍了富锂材料的结构特点、锂嵌脱机理和改性方法,并展望了今后的研究方向.     

锂离子二次电池正极材料 Li~0~.~7~5Na~0~.~2~5MnO~1~.~9~2I~0~.~0~8化合物 的合成与表征

采用LiOH·H~2O为锂源,化学纯MnO~2(CMD)为锰源,NaI为添加剂,乙腈为非水介质,在常温常压下合成了锂离子二次电池正极材料Li~0~.~7~5Na~0~.~2~5MnO~1~.~9~2I~0~.~0~8化合物,并采用XRD,BET,TEM及电化学测试等手段对该化合物进行了表征。结果表明该化合物原料呈非晶态超细粉末,平均粒径在45～60nm之间,具有较大的比表面积(35～48m^2/g)。经260℃真空干燥后,样品转化为纳米晶态,以该化合物作正极材料与Li作对电极构成的锂电池,在1.5～4.3V之间和0.353mA/cm^2条件下恒流充放电,首次充放电比容量超过280(mA·h)/g。充放电效率大于95％。循环20次后,其充放电比容量仍大于260(mA·h)/g,是很有应用前景的锂离子二次电池正极材料。     

High capacity SnxSbyCuz composite anodes for lithium ion batteries

To increase the volumetric discharge capacity of negative electrode for rechargeable lithium batteries, a composite anode Sn_xSb_yCu_z has been synthesized by using high energy mechanical ball milling method. The synthesized composite anode materials have been characterized by X-ray diffraction and SEM analysis. The charge/discharge characteristics of the fabricated coin cells have been evaluated galvanostatically in the potential range 0.01–2 V using 1 M LiPF₆ in 1:1 EC/DEC as electrolyte. Results indicate that the composition with 90 wt% Sn, 8 wt% Sb and 2 wt% Cu delivers an average discharge capacity of 740 mAh g⁻¹ over the investigated 50 cycles which is a potential candidate for use as an anode material for lithium rechargeable cells.