锂离子电池及性能研究

  • 格式:doc
  • 大小:167.50 KB
  • 文档页数:17

毕业设计(论文)

题 目 锂离子电池正极材料尖晶石

锰酸锂的制备及性能研究

系 (院) 化学与化工系

专 业 应用化工技术

班 级

学生姓名

学 号

指导教师

职 称 讲师

二〇 年 月 日

锂离子电池正极材料尖晶石锰酸锂的制备及性能研究

摘要 锂离子电池因其优越的电化学性能、高比容量、长循环寿命、高能量密度以及放电电压高、体积小、环保绿色等特性在过去的十年内得到了迅猛发展。作为锂离子电池重要组成部分的正极材料也成为当前该领域研究的热点之一。尖晶石型LiMn2O4以其高能量密度、价格低廉、无环境污染等特点而被视为最具发展潜力的锂离子电池的正极材料之一。对高温反应而言,包括高温固相反应法、熔融浸渍法、微波烧结法及其他改进的方法;在低温反应方法中,主要讨论了溶胶凝胶法、共沉淀法及乳化干燥法等。体相掺杂和表面修饰是抑制尖晶石型LiMn2O4容量衰减的有效方法。从锰酸锂的制备与改性研究方面综述了锂离子电池正极材料锰酸锂的研究进展,在此基础上提出了正极材料锰酸锂的发展方向。

关键词: 锂离子电池;正极材料;锰酸锂 Preparation and modification of LiMn2O4 as cathode

material for lithium ion batteries

Abstract

Lithium-ion batteries have developed greatly because of its

excellent electrochemical properties, high specific capacity, long cycle

performance, high energy density and other merits, such as high

discharge voltage, small volume and less harm to environment. Spinal

LiMn2O4 is a potential cathode material of Li-ion batteries because of its

high energy density, low cost and no pollution to environment, etc.

Among the synthetic methods, conventional solid-state reaction method,

melt-impregnation method, microwave sintering method an-dot her

modified method are included in the high-temperature synthetic methods

whereas the sol-gel method, co-precipitation method and micro-emulsion

method are included in the low-temperature methods. Doping and surface

modification are the effectively ways to restrain the capacity loss in

cycling. Research progress in recent years on preparation and

modification of lithium manganate cathode material was introduced, and

based on that, the major developing trend was prospected.

Key words: lithium ion battery;cathode material;LiMn2O4 目 录

引言 „„„„„„„„„„„„„„„„„„„„„„„„„„„„„„„ 1

第一章 锂离子电池的简介

1.1 锂离子电池的发展 „„„„„„„„„„„„„„„„„„„„„„„ 2

1.2 锂离子电池的工作原理 „„„„„„„„„„„„„„„„„„„„„ 3

1.3锂离子电池正极材料的选择原则和尖晶石型LiMn2O4的晶体结构„„„„„„„„„„„„„„„„„„„„„„„„„„„„„„„„„4

1.3.1 正极材料的选择原则„„„„„„„„„„„„„„„„„„„„„„4

1.3.2尖晶石型LiMn2O4的晶体结构„„„„„„„„„„„„„„„„„„

5

第二章 锂锰氧化物制备方法研究现状

2.1 固相合成法 „„„„„„„„„„„„„„„„„„„„„„„„„„ 7

2.1.1 传统高温固相法 „„„„„„„„„„„„„„„„„„„„„„„ 7

2.1.2 熔融浸渍法 „„„„„„„„„„„„„„„„„„„„„„„„„ 7

2.1.3 两段烧结法 „„„„„„„„„„„„„„„„„„„„„„„„„ 8

2.1.4 其他固相改进方法 „„„„„„„„„„„„„„„„„„„„„„ 8

2.2 液相合成反应法 „„„„„„„„„„„„„„„„„„„„„„„„ 8

2.2.1 溶胶凝胶法 „„„„„„„„„„„„„„„„„„„„„„„„„ 8

2.2.2 共沉淀法 „„„„„„„„„„„„„„„„„„„„„„„„„„ 9

2.2.3 乳化干燥法 „„„„„„„„„„„„„„„„„„„„„„„„„ 9

第三章 尖晶石型锰酸锂的性能研究

3.1 合成温度对材料性能的影响 „„„„„„„„„„„„„„„„„„„10

3.2 尖晶石型锰酸锂的容量衰减机理 „„„„„„„„„„„„„„„„„10 3.3 掺入等量不同阴阳离子对材料性能的影响 „„„„„„„„„„„„„11

结论 „„„„„„„„„„„„„„„„„„„„„„„„„„„„„„„12

参考文献 „„„„„„„„„„„„„„„„„„„„„„„„„„„„„13

引言

锂离子电池分为液态锂离子电池(LIB)和聚合物锂离子电池(PLIB)。液锂离子电池自1990年开发成功以来,由于它具有能量高、工作电压高、应用温度范围宽、自放电率低、循环寿命长、无污染、安全性能好等独特优势,现已广泛用作袖珍贵重电器,如移动电话、便携式计算机、摄像机、照相机等的电源,并已在航空、航天、航海、人赵卫星、小型医疗仪器及军用通讯设备领域中逐步代替传统电池。聚合物锂离子电池除具有液态锂离子电池的优点外,由于采用不流动电解质,还具有安全性能更好的优点,因此,可以制成任意形状和任意尺寸的超薄型电池,因而更适合用作微型电器的电源,应用范围更广。虽然锂离子电池己经商业化并得到广泛应用,但该领域仍是今后研究的热点,目的是降低成本,提高容量和延长循环寿命。今后的主要发展方向为用Ni或Mn取代目前正极材料中的Co,降低成本,减小Co对环境造成的污染改善正极材料性能是提高锂离子电池性能的关键,因为正极材料的比容量每提高50%,电池的功率密度会提高28%,而负极材料的比容量每提高50%,电池的功率密度相应的只会提高13%。因此,研究锂离子二次电池正极材料,对于发展和改进锂离子二次电池,具有重要的现实意义。锂离子电池是以锂离子能够自由脱嵌的化合物作为正、负极材料的新一代电池。它具有输出电压高、比能量高、循环寿命长、自放电小、无记忆效应、安全性好等特点。决定锂离子电池性能的重要因素之一是正极材料,研究和开发高性能的正极材料也就成为目前锂离子电池发展的关键所在。商品化LiCoO2的循环性能好,但比容量偏低、价格高,对环境污染较大。而具备比容量较高、原料资源丰富、价格便宜、环境友好等特点的尖晶石型LiMn2O4正极材料成为替代已商业化的LiCoO2的首选材料。 近年来,针对尖晶石LiMn2O4容量衰减机理,国内外展开了一系列的关于尖晶石锰酸锂的制备和性能研究,并采用掺杂不同物质来改变其性能。

第一章 锂离子电池的简介

1.1 锂离子电池的发展

锂是自然界金属中标准电位最负(--3.045V),质量最轻(6.939g/mol),比容量最高(3800mAh/g)的金属。以锂为负极组成的一次锂电池,具有比容量大、电压高、放电电压平稳,工作温度范围宽(--40—70℃)、低温性好、储存寿命长等优点。正是基于以上优点,到目前一次锂电池已经大规模商品化,广泛应用于计算机、照相机、心脏起搏器、电子手表、无线电通信、导弹点火装置等领域。锂二次电池的研究最早始于二十世纪六七十年代的石油危机,到八十年代中期,锂二次电池发展最快,开发了以Li/MoS2、Li/MnO2、Li/V2O5为主的二次锂电池。但锂二次电池再充放电过程中,一方面,由于金属锂电极表面不均匀,造成锂不均匀沉积产生锂枝晶,当锂枝晶发展到一定程度是造成短路,引起安全问题;另一方面,金属锂会和电解液发生反应生成钝化膜,使锂电极逐渐粉末化而失去活性,导致充放电效率低,循环寿命短的缺点。针对锂电池的缺点,人们尝试采用优化电解质组成,在电解质中加入添加剂对金属锂表面进行修饰,或采用固体高聚物电解质的办法以及锂合金来代替金属锂的办法来克服二次锂电池的缺点但实际效果都不理想。直到1980年阿曼德(Armand)提出用嵌入和脱出物质作为二次锂电池的电极想法后,1985年日本SONY公司开始了锂离子电池的实用化研究,并于1990年率先开发了以CoLiO2为正极,石油焦炭为负极的锂离子电池,从此引发了锂离子电池全球性的研制开发热潮。

因此,可见锂离子电池是在锂电池的基础上发展起来的一种新型能源电池,它与锂电池相比最大的优点在于用锂离子嵌入、脱出材料来代替金属锂,从而从根本上克服了锂负极的钝化和枝晶穿透问题。这样,既保持了锂离子电池的高容量、高电压等许多优点,还大大提高了电池的充放电效率和循环寿命,并且在充放电时不引起电极体积的明显变化,从而使电池的安全性能得到了较大的改善。由于锂离子电池的优良性能,近年来已经成为世界性的研究热点,锂离子电池被称为“二十一世纪最有发展的理想电源”等。

锂离子电池目前有液态锂离子电池(LIB)和聚合物锂离子电池(PLIB)两类。其中,液态锂离子电池是指Li+嵌入化合物为正、负极的二次电池。正极采用锂化合物LiCoO2,LiNiO2或LiMn2O4,负极采用锂-碳层间化合物LixC6。电解质为溶解锂盐LiPF6,LiAsF6等的有机溶液。

聚合物锂离子电池的正极和负极与液态锂离子电池相同,只是原来的液态电解质改为含有锂盐的凝胶聚合物电解质。目前,正在研究和开发的电池正极也采用聚合物的聚合物锂离子电池。

1.2 锂离子电池的工作原理

锂离子电池是将化学能转化为电能及其相反过程的一种化学电源,它包括正极、负极、隔膜、电解液。对于一个完整的电池来说,电解液是用来分隔离子传输和电子传输的,锂离子主要集中在此。隔膜是放在电池材料的正负极之间,允许离子通过而电子不能通过的传输通道。以层状LiCoO2为正极,层状石墨为负极的锂离子二次电池为例,锂离子电池的工作原理如下图所示。