碳酸锂在水和NaCl-KCl溶液体系中溶解度的在线测定

碳酸锂溶解度在工业结晶生产中是十分重要的基础数据。采用浸入式红外探头和拉曼探头在线监测溶液体系中CO₃^2-和碳酸锂的特征峰峰强的变化,依据Lambert-Beer定律得出溶液体系中实时在线测定碳酸锂的溶解度。通过在线测定,测得碳酸锂在氯化钠-氯化钾溶液（c_NaCl=0.446 6 mol/L,c_KCl=0.015 8 mol/L）中的溶解度高于在水中的溶解度值。实验测试出的水中碳酸锂的溶解度数据还能与Van′t Hoff方程较好地关联,进一步测算碳酸锂在其他温度下水中的溶解度值。此外,该方法测定的碳酸锂在水中的溶解度数据比文献值中采用重量分析法测试出的溶解度数据偏小,是因为测试装置不同造成的。     

机械活化-湿化学合成LiMn2O4的组成、结构与表征

以MnO2和LiOH·H2O为原料,采用机械活化与湿化学集成的方法,在水溶液中直接合成了结晶态的尖晶石锂锰氧化物.当锂含量介于3.78%～4.35%之间时,所得锂锰氧化物为纳米级球形粉末,以尖晶石结构为主,含极少量的Mn3O4杂相;在300～800℃温度范围内热处理后,Mn3O4杂相消失,尖晶石结构更趋完善.所合成的含锂5.80%的高锂样品则以LiMnO2层状结构为主,含少量Mn3O4杂相,其SEM形貌为片状;在300～700℃下热处理8 h后,层状LiMnO2转变成尖晶石LiMn2O4,Mn3O4杂相峰明显减弱并随热处理温度的升高而消失;当温度升高至700～800℃时,开始出现缺锂的Li1-xMn2O4相.结果表明:该法制备锂锰氧化物可实现锂、锰、氧在原子级水平的均匀混合,所得产物的热稳定性能良好,其化学计量组成与结构易于调整和控制.     

LiNi1-xMxO2 (M =Co3+, Al3+)的制备与性能

采用球形Ni(OH)2和LiNO3、CoO、Al(OH)3为原料，在空气气氛条件下700℃恒温8h，合成了锂离子电池正极材料LiNixCo1-xO2和LiNi0.75Al0.25O2。X射线衍射分析表明合成的材料粉末结晶良好，具有规整的α-NaFeO2层状结构；SEM分析表明粉末颗粒呈球形，粒径约为7μm。充放电测试表明：合成的LiNixCo1-xO2正极材料的充电比容量为160mAh／g，放电比容量为152mAh／g；LiNi0.75Al0.25O2正极材料的充电比容量为140mAh／g，放电比容量为129mAh／g；这两种正极材料具有优良的电化学性能。     

基于容量参数的二次电池嵌入型电极材料固相扩散系数的测定方法

介绍了一种以容量参数为主变量的测定锂二次电池中电极材料固相扩散系数的方法.该方法只需颗粒半径这一辅助参数,通过球型扩散模型建立了恒流-恒压充电容量(RPG)比,进一步发展成为容量间歇滴定技术(CITT).采用RPG法可在较宽的电压范围内测定嵌入型电极材料的平均固相扩散系数,实验结果重现性好.由RPG法测得0～1.5 V时锂离子在石墨电极中的平均固相扩散系数值为1.055×10-10cm2/s.由CITT技术测得锂离子在LiMn2 O4中的固相扩散系数在3.95 V和4.12 V左右存在个两个极小峰,且随着循环次数的增加,扩散系数值逐渐增大.     

Phase transition of lithiated-spinel Li2Mn2O4 at high temperature

1 Introduction Lithium manganese oxides are the most attractive cathode materials for rechargeable lithium-ion batteries because of their low-cost and less toxicity when compared with either cobaltates or nickelates[1?3]. Among these oxides, the spinel-fr…     

锂离子电池正极材料第一原理计算研究

利用第一原理计算方法可分析和预测锂-金属氧化物电池正极材料在Li离子嵌入脱出过程中的电势和稳定性等性能。本文详细介绍了第一原理计算方法的理论背景以及目前LiCoO2正极材料计算研究的现状。利用此方法对LiNiO2及多组分材料掺杂进行研究是今后工作的重点。     

Effect of annealing treatment on electrochemical property of LiNi0.5Mn1.5O4 spinel

LiNi0.5Mn1.5O4 was prepared under different cooling conditions. The electrochemical properties of LiNi0.5Mn1.5O4 prepared under different cooling conditions were investigated. The results show that LiNi0.5Mn1.5O4 synthesized with or without annealing treatment has similar X-ray diffraction patterns that can be indexed to cubic spinel structure. The mass loss occurring above 650℃ during the heating process can be mostly gained during the cooling process. LiNi0.5Mn1.5O4 synthesized with an annealing treatment exhibits almost one voltage plateau at around 4.7 V and higher capacity with a quick fading upon cycling, whereas LiNi0.5Mn1.5O4 synthesized without annealing treatment shows two voltage plateaus at around 4.1 and 4.7 V and superior capacity retention upon cycling both at rates of 1/7C and 1 C, though the capacity is not high.     

Synthesis and electrochemical properties of Th-doped LiMn2O4 powders for lithium-ion batteries

To improve the cycle performance of eco-friendly and cost-effective spinel LiMN2O4 as the Li secondary batteries, the Th-doped LiThxMn1-xO4 spinel powers were synthesized by solid-state method. The starting materials, Li2CO3,MnO2 and Th(NO3)4·4H2O, were mixed uniformly using a traditional ball milling, which resulted in a uniform particle size distribution in the mixed powers. Tests of X-ray diffraction, SEM, impedance spectra and charge-discharge were carried out for LiThxMn1-xO4 cathode materials. Results show that the synthesized LiTh0.01Mn1.99O4 material exhibits standard spinel structure, regular particle morphology and excellent property of charge-discharge for big current. The capacity retention of the material modified by doping Th is more than 85.1% of the first discharge specific capacity of 111.5 mAh·g -1 after 20 cycles at the current rate 1C, while the pristine LiMN2O4 is only 57% of the first discharge specific capacity of 110.2 mAh·g-1 after the same cycles at the same current rate.     

绿色溶剂碳酸二甲酯处理含酚废水研究

用绿色溶剂碳酸二甲酯 (DMC)对含酚废水进行了萃取处理 ,研究了时间、pH、溶剂组成、溶剂比等对萃取的影响。实验结果表明 ,DMC萃取苯酚的过程为物理溶解过程 ,因此萃取过程在几分钟之内就能达到平衡 ,而且萃取过程基本不受 pH值的影响。随着平衡水相浓度的增加 ,平衡有机相浓度增加 ,而且分配系数也增加。以 5 0 %DMC 正己烷为萃取剂 ,三级萃取 5g/L的苯酚废水 ,萃残液中的酚浓度降到了 4.82mg/L。