以碳粉为负极材料制备锂离子电池及电池性能测试

在能量存储技术中,锂离子电池是高能量密度的电化学电源.以碳为负极材料,涂膜制备了负极片,以锂片为正极片制备了CR2016锂离子电池,并对其性能进行了测试,分析了碳粉为锂电负极材料的特性.     

尖晶石LiMn2O4及其衍生物的电化学阻抗特性

尖晶石LiMn2O4(以下简称LMO)是锂离子电池正极材料之一，具有价格低廉，资源丰富的特点。锂离子电池的充放电过程实际上是锂离子从正极脱嵌、再嵌入正极的过程。因此Li^ 在正负极材料及电解液中的扩散性能影响着电池的电性能，通过其电化学阻抗谱可得出锂离子的扩散系数及电导率等参数。     

锂离子电池用具有分级三维离子电子混合导电网络结构的纳微复合电极材料

文章评述了分级三维离子电子混合导电网络结构和具有该结构的纳微复合电极材料在锂离子电池中的应用等方面的最新研究工作进展.首先介绍了纳微复合电极结构相关概念及其优缺点,然后列举了一些运用此概念设计并构筑出的电极材料实例.研究证明,此新型电极结构能够大幅提高锂离子电池电极材料的储锂性能,并且该结构设计还可推广到其他电化学储能...     

基于电化学模型的锂离子电池多尺度建模及其简化方法

锂离子电池的精确建模和状态估计对于电动汽车电池管理系统非常重要,准二维(P2D)电化学模型由于计算复杂,难以直接应用于电池管理的参数在线估计和实时控制中.本文基于多孔电极理论和浓度理论,提出一种考虑锂离子液相动力学的简化准二维(SP2D)模型.忽略锂离子孔壁流量沿电极厚度方向的变化求解SP2D模型所描述的锂离子电池锂浓度分布,基于锂离子电池电化学平均动力学行为求解固相和液相电势变化,推导出电池电压计算的简化表达式;采用恒流、脉冲以及城市循环工况放电电流对比分析了严格P2D模型与SP2D模型的终端电压和浓度分布.结果表明:SP2D模型在保持较高计算精度的同时,可显著提高计算效率.     

石墨烯在锂离子电池负极材料中的应用

正1.引言化石能源日益短缺的危机使得可再生能源和能量存储技术受到广泛关注。基于在能量存储方面的优异表现,锂离子电池被认为是极具发展前景的电化学储能体系之一,其在民用、国防和航空航天等领域显示出强大的应用潜力。锂离子电池又称摇椅电池,其储放能过程如图1所示。锂离子电池的性能主要受到电极材料、电解质和器件组装技术等因素的制约,而正负极材料是决定电池性能的关键所在。现阶段研究的负极材料,依据电极反应的机理来划分,主要有嵌入型、合金反应型以及转换反应型三大类。然而由于三种类型电极材料的固有缺点如理论     

基于电化学-热耦合模型研究隔膜孔隙结构对锂离子电池性能的影响机制

隔膜孔隙结构对锂离子电池性能具有重要的影响,本文提出了可准确描述充放电过程中锂离子电池内部复杂物理化学现象的电化学-热耦合模型,发现该模型较文献中模型的计算结果更接近实验测试数据.利用该模型探讨了隔膜孔隙率与扭曲率分别对锂离子电池性能的影响规律,发现减小孔隙率或增大扭曲率,电池输出电压、最大放电容量和平均输出功率均不断降低,电池表面温度和温升速度均不断升高;当孔隙率减小或扭曲率增大到一定程度时,放电初期电池输出电压均会出现先下降后回升的现象,且孔隙率越小或扭曲率越大,其下降的幅度越大、速度越快,回升所需时间也越长;要确保其不低于截止电压,隔膜扭曲率必须小于临界扭曲率(其下降至最低点刚好等于截止电压时的隔膜扭曲率).综合分析了放电过程中电池内部各电化学参量和产热量的动态分布规律,发现隔膜孔隙率和扭曲率主要影响放电末期电极膜片内部电化学反应以及其他放电时刻电解液中有效Li~+扩散(传导)系数.     

三维自支撑甲苯灰微球锂硫电池正极材料的制备与性能研究

新能源交通工具的飞速发展激发了人们对高能量密度电池技术的探索,锂硫电池因为具有较高的理论能量密度被视为锂离子电池的替代品。但由于硫具有导电性差和多硫化物的穿梭效应等问题,锂硫电池的商业化应用仍面临巨大的挑战。基于此,为改善锂硫电池的性能,设计了一种高导电性三维支撑的正极结构:多级交联的三维导电网络能够有效提高正极材料导电性;纳米碳球堆叠形成的孔道结构提供了丰富的反应活性点位和体积缓冲空间。测试结果表明,这种新型正极结构在0.15 C的电流倍率下放电比容量高达1 124 mAh g-1;在2 C的大电流倍率充放电200次循环后,放电比容量仍能保持在591 mAh g~(-1),表现出良好的循环稳定性和电化学稳定性。     

基于数据驱动的卫星锂离子电池寿命预测方法

锂离子电池由于具有工作电压高、体积小、质量轻、比能量高、寿命长和自放电率小等优点,成为 替代传统镍氢、镍镉电池的第三代航天器用储能电源。寿命预测是锂离子电池健康管理的重要方面,是掌 握电源衰退的重要手段。锂离子电池剩余使用寿命预测问题已成为电子系统健康管理领域的研究热点和具 有挑战性的问题之一。本文基于NASA埃姆斯中心的锂离子电池地面试验采集数据,首先分析了3种类型 的锂离子电池预测方法,之后重点研究了几种有效的数据驱动的锂离子电池寿命预测方法,并对各种预测 方法的效果进行了评价。实验结果表明,本文提出的方法能够有效的用于基于数据驱动的锂离子电池寿命 预测中,具有较强的工程应用价值。     

锂离子电池过往与未来

2019年诺贝尔化学奖授予从事锂离子电池研究的三位杰出科学家,让锂离子电池这项技术成为社会大众视野焦点,也表明了锂离子电池在推动人类社会科学技术进步中所做出的贡献得到了科学界一致认可。文章结合三位获奖者的工作对锂离子电池的发明及其过往历史做一简单梳理和介绍,并在此基础上谈谈锂离子电池技术未来面临的机遇和存在的挑战。     

全固态锂离子电池内部热输运研究前沿

本文简要阐述了全固态锂离子电池的特点及其内部热输运研究的意义.介绍并总结了国内外与正极材料、负极材料、固态电解质,以及电极与电解质界面热输运性质相关的实验和理论工作.针对脱嵌锂过程对电极材料热导率的影响机理尚不明确,非晶态转变对电极材料热输运研究的挑战,界面热输运模型与方法不足等问题,系统梳理了全固态锂离子电池内部热输运的重要前沿科学问题.     

Surface structure evolution of cathode materials for Li-ion batteries

Lithium ion batteries are important electrochemical energy storage devices for consumer electronics and the most promising candidates for electrical/hybrid vehicles. The surface chemistry influences the performance of the batteries significantly. In this short review, the evolution of the surface structure of the cathode materials at different states of the pristine, storage and electrochemical reactions are summarized. The main methods for the surface modification are also introduced.     

Nanomaterials for electrochemical energy storage

The development of nanotechnology in the past two decades has generated great capability of controlling materials at the nanometer scale and has enabled exciting opportunities to design materials with desirable electronic, ionic, photonic, and mechanical properties. This development has also contributed to tile advance in energy storage, which is a critical technology in this century. In this article, we will review how the rational design of nanostructured materials has addressed the challenges of batteries and electrochemical capacitors and led to high-performance electrochemical energy storage devices. Four specific material systems will be discussed： i） nanostructured alloy anodes for Li-batteries, ii） nanostructured sulfur cathodes for Li-batteries, iii） nanoporous open- framework battery electrodes, and iv） nanostructured electrodes for electrochemical capacitors.     

Controllable Formation of Niobium Nitride/Nitrogen‐Doped Graphene Nanocomposites as Anode Materials for Lithium‐Ion Capacitors

Niobium nitride/nitrogen‐doped graphene nanosheet hybrid materials are prepared by a simple hydrothermal method combined with ammonia annealing and their electrochemical performance is reported. It is found by scanning electron microscopy (SEM) and transmission electron microscopy (TEM) that the as‐obtained niobium nitride nanoparticles are about 10–15 nm in size and homogeneously anchored on graphene. A non‐aqueous lithium‐ion capacitor is fabricated with an optimized mass loading of activated carbon cathode and the niobium nitride/nitrogen‐doped graphene nanosheet anode, which delivers high energy densities of 122.7–98.4 W h kg^?1 at power densities of 100–2000 W kg^?1, respectively. The capacity retention is 81.7% after 1000 cycles at a current density of 500 mA g^?1. The high energy and power of this hybrid capacitor bridges the gap between conventional high specific energy lithium‐ion batteries and high specific power electrochemical capacitors, which holds great potential applications in energy storage for hybrid electric vehicles.     

纳米储锂材料和锂离子电池

简单综述了锂离子电池的基本原理和发展现状，对中国科学院物理研究所固体离子学课题组在纳米储锂材料方面的研究进展做了介绍。用HRTEM等手段研究了纳米SnO、纳米Si以及纳米SnSb合金在Li入脱嵌过程中结构的变化。着重介绍了一种具有纳米微孔的球形硬碳材料和纳米SnSb合金钉扎的复合负极材料，在高功率密度和高能量密度锂离子电池方面具有广阔应用前景。     

Copper‐Based Nanomaterials for High‐Performance Lithium‐Ion Batteries

With the increasing energy demands for electronic devices and electrical vehicles, anode materials for lithium‐ion batteries with high specific capacity, good cyclic and rate performance become one of the focal areas of research. A class of them is the copper‐based nanomaterials that have thermal and chemical stability, high theoretical specific capacity, low price and environment friendliness. Now this kind of nanomaterials has been recognized as one of the critical materials for lithium‐ion batteries due to the predicted future market growth. Current status of different copper‐based materials which produced already are discussed. In this review, comprehensive summaries and evaluations are given in synthesis strategies, tailored material properties and different electrochemical performance. Recent progress of general copper‐based nanomaterials for lithium‐ion batteries is carefully presented.     

Thermal transport in lithium-ion battery: A micro perspective for thermal management

In recent years, lithium ion (Li-ion) batteries have served as significant power sources in portable electronic devices and electric vehicles because of their high energy density and rate capability. There are growing concerns towards the safety of Li-ion batteries, in which thermal conductivities of anodes, cathodes, electrolytes and separator play key roles for determining the thermal energy transport in Li-ion battery. In this review, we summarize the state-of-the-art studies on the thermal conductivities of commonly used anodes, cathodes, electrolytes and separator in Li-ion batteries, including both theoretical and experimental reports. First, the thermal conductivities of anodes and cathodes are discussed, and the effects of delithiation degree and temperature of materials are also discussed. Then, we review the thermal conductivities of commonly used electrolytes, especially on solid electrolytes. Finally, the basic concept of interfacial thermal conductance and simulation methods are presented, as well as the interfacial thermal conductance between separator and cathodes. This perspective review would provide atomic perspective knowledge to understand thermal transport in Li-ion battery, which will be beneficial to the thermal management and temperature control in electrochemical energy storage devices.     

Wavy structures for stretchable energy storage devices: Structural design and implementation

The application of wavy structures in stretchable electrochemical energy storage devices is reviewed. First, the mechanical analysis of wavy structures, specific to flexible electronics, is introduced. Second, stretchable electrochemical energy storage devices with wavy structures are discussed. Finally, the present problems and challenges are reviewed, and possible directions for future research are outlined.     

Cruising in ceramics—discovering new structures for all-solid-state batteries—fundamentals,materials, and performances

Energy storage research has drawn much attention recently due to increasing demand for carbon neutral electrical energy from renewable energy sources such as solar, wind, and hydrothermal. Various electrochemical energy storage and conversion technologies are being considered for their integration into smart grid systems, of which batteries seem to play a vital role due to their wide range of energy densities. In this review, we provide the current status and recent advances in solid-state (ceramic) electrolytes based on inorganic compounds for all-solid-state batteries. This paper is specifically focused on the fundamentals, materials, and performances of solid electrolytes in batteries. A wide spectrum of inorganic solid-state electrolytes is presented in terms of their chemical composition, crystal structure, and ion conduction mechanism. Furthermore, the advantages and main issues associated with different types of inorganic solid electrolytes, including β-alumina, NASICON and LISICON-type, perovskites, and garnet-type for all-solid-state batteries are presented. Among these solid electrolytes, Zr and Ta-based Li-stuffed garnets exhibit high Li-ion conductivity, electrochemical stability window (up to 6  V/Li at room temperature), and chemical stability against reaction with molten elemental Li. However, their stability under humidity and carbon dioxide should be improved to decrease the fabrication and operational costs.     

Structural Strategies for Germanium‐Based Anode Materials to Enhance Lithium Storage

Recently, germanium (Ge) has been arousing increasing interest as an anode for lithium‐ion batteries (LIBs) and other energy storage devices due to its high theoretical capacity (1600 mAh g^?1) and low operating voltage. There are still some critical problems to be solved before Ge can meet the high requirements for practical applications. In this Review, a series of attempts on rational design and synthesis of Ge‐based anode materials during the past few years are summarized. Structural and composition strategies that could resolve the issue of vast volume changes in Ge during cycling and enhance their electrochemical properties are focused on. The main strategies include designing nanostructures and forming Ge‐based composites and Ge‐based alloys. Lastly, the challenges for practical implementation of Ge anodes within the context of current LIB systems are discussed.