Synthesis and electrochemical performance of LiNi0.5Mn1.5O4 spinel compound

Spinel compound LiNi_0.5Mn_1.5O₄ was synthesized by a chemical wet method. Mn(NO₃)₂, Ni(NO₃)₂·6H₂O, NH₄HCO₃ and LiOH·H₂O were used as the starting materials. At first, Mn(NO₃)₂ and Ni(NO₃)₂·6H₂O reacted with NH₄HCO₃ to produce a precursor, then the precursor reacted with LiOH·H₂O to synthesize product LiNi_0.5Mn_1.5O₄. The product showed a single spinel phase under appropriate calcination conditions, and exhibited a high voltage plateau at about 4.6-4.8 V in the charge/discharge process. The LiNi_0.5Mn_1.5O₄ had a discharge specific capacity of 118 mAh/g at about 4.6 V and 126 mAh/g in total in the first cycle at a discharge current density of 2 mA/cm². After 50 cycles, the total discharge capacity was above 118 mAh/g.     

湿式氧化处理乙烯裂解废碱液

文章研究了WAO处理乙烯裂解废碱液的方法。在2L高压釜中进行了乙烯废碱液的湿式氧化实验研究，重点考察了反应温度、停留时间对乙烯废碱液中COD、S^2-,酚的含量的影响。结果表明，湿式氧化处理乙烯裂解废碱液是可行的，处理后污水中COD、S^2-,酚的去除率分别达到40％、98％和30％，达到了排放标准。     

Nickel foam and carbon felt applications for sodium polysulfide/bromine redox flow battery electrodes

The first use of nickel foam (NF) as electrocatalytic negative electrode in a polysulfide/bromine battery (PSB) is described. The performance of a PSB employing NF and polyacrylonitrile (PAN)-based carbon felt (CF) as negative and positive electrode materials, respectively, was evaluated by constant current charge-discharge tests in a single cell. Charge/discharge curves of the cell, positive and negative electrodes show that the rapid fall in cell voltage is due to the drop of positive potential caused by depletion of Br₂ dissolved in the catholyte at the end of discharge. Cell voltage efficiency was limited by the relatively high internal ohmic resistance drop (iR drop). Polarization curves indicated that both NF and CF have excellent catalytic activity for the positive and negative redox reactions of PSB. The average energy efficiency of the single cell designed in this work could be as high as 77.2% at 40 mA cm⁻² during 48 charge-discharge cycles.     

用工业废碱水处理反渗透法高含盐排放浓水

反渗透处理装置排放的浓水含盐量很高，如果不经处理直接排放势必对周围环境造成污染和水的浪费，氧化铝生产工艺废水中含有大量的碳酸钠、苛性碱等碱类物质，pH值达到13左右，回水量约2000m^3／h，用这些废水和反渗透浓水混合进行软化处理，降低浓水中的钙镁离子含量，并对难去除的硫酸盐进行稀释降低浓度，回用到蒸发循环水系统作为补充用水、氧化铝生产部分工艺用水、设备冷却用水，达到浓水回收再利用的目的。该方案实施后效果十分显著，回收反渗透浓水约60m^3／h，减少污水系统补充新水，降低生产用水费用约每年176万元。     

沥青炭微球在锂离子电池中的应用与市场前景

介绍中间相沥青炭微球的制备方法和发展现状，分析了其在锂离子二次电池等方面的应用及国内外市场前景。     

无汞碱性锌锰电池贮存期漏液原因探讨

介绍了无汞锌粉中的杂质、析气量、锌粉形貌以及电池密封圈对无汞碱性电池高温贮存性能的影响，探讨了电池漏液的原因，提出了防止漏液的措施。     

锂离子电池正极材料LixMn2O4研究进展

总结了锂离子电池正极材料LixMn2O4的合成方法，归纳了造成容量衰减问题的原因和目前为解决该问题所采用的各种方法，并且对下一步的研究工作进行了展望。     

利用废旧锌锰电池制取锌盐和氧化锌的研究

以废旧锌锰电池为研究对象,采用湿法回收技术,制备ZnSO4.7H2O,ZnCO3和ZnO。结果表明,Zn溶解时间随着H2SO4浓度而变,当H2SO4浓度为3 mol/L时,溶解耗时仅为5 h,ZnSO4.7H2O产率可达93.44%。在Na2CO3,NaHCO3,(NH4)2CO3三种沉淀剂中,(NH4)2CO3的沉淀效果最好,制备的ZnCO3颗粒细小,在1 073.2 K条件下,其分解效率可达88.75%。     

四氟硼锂和六氟砷锂的合成与拉曼光谱分析

介绍了合成高纯无水的ＬｉＢＦ４和ＬｉＡｓＦ６的新方法，并讨论了其合成条件，指出制备多孔状ＬｉＦ和控制反应温度是合成的关键。     

Enhanced electrochemical performance and thermal stability of La2O3-coated LiCoO2

An enhanced electrochemical performance LiCoO₂ cathode was synthesized by coating with various wt.% of La₂O₃ to the LiCoO₂ particle surfaces by a polymeric method, followed by calcination at 923 K for 4 h in air. The surface-coated materials were characterized by XRD, TGA, SEM, TEM, BET and XPS/ESCA techniques. XRD patterns of La₂O₃-coated LiCoO₂ revealed that the coating did not affect the crystal structure, α-NaFeO₂, of the cathode material compared to pristine LiCoO₂. TEM images showed a compact coating layer on the surface of the core material that had an average thickness of about ∼15 nm. XPS data illustrated that the presence of two different environmental O 1s ions corresponds to the surface-coated La₂O₃ and core material. The electrochemical performance of the coated materials by galvanostatic cycling studies suggest that 2.0 wt.% coated La₂O₃ on LiCoO₂ improved cycle stability (284 cycles) by a factor of ∼7 times over the pristine LiCoO₂ cathode material and also demonstrated excellent cell cycle stability when charged at high voltages (4.4, 4.5 and 4.6 V). Impedance spectroscopy demonstrated that the enhanced performance of the coated materials is attributed to slower impedance growth during the charge-discharge processes. The DSC curve revealed that the exothermic peak corresponding to the release of oxygen at ∼464 K was significantly smaller for the La₂O₃-coated cathode material and recognized its high thermal stability.