电解溶解

The reasons of the capacity attenuation have primarily to accompany with the Li~+ ion embedding material on discharge process the effect of Jahn-Teller of the occurrence, the deliquescence of the cathode manganese in the material and the decomposition of the electrolyte.

在锂离子电池众多的正极材料中，尖晶石型LiMn_2O_4化合物，由于其原材料资源丰富，价格低，环境污染小，合成工艺简单，成为最有希望取代LiCoO_2的材料，但LiMn_2O_4存在容量衰减大，循环寿命短等问题，阻碍了其商品化应用；容量衰减的原因主要有在放电过程中伴随着Li~+离子嵌入发生的Jahn-Teller效应，正极材(来源：AacBCbd论4b文网www.abclunwen.com)料中的锰的溶解和电解液的分解。

The research uses electroanalysis principle to change reaction condition and blow the air into the cathode all the time.

根据电解原理，改变试验条件，并向阴极不断通入空气，测定电解过程中阳极溶解铁和阴极过氧化氢的产量。

FTIR results show that LiPF_6 decomposes at a certain degree after storage.And the solvent in the electrolyte is oxided to small molecular weight substance.The polarization of electrode,Mn dissolution and Oxygen deficiency in the LiMn_2O_4,decomposition and oxygenation of electrolyte,Li+ consuming during the incrassated and compacted SEI film is the reason of capacity fading during storage.

电极表面极化、正极材料中Mn溶解以及氧缺陷、SEI膜增厚所消耗的活性锂、电解液的分解和氧化是导致储存后锰酸锂电池储存后容量衰减的主要原因。

Results showed that it was reasonable to evaluate the content of non - dissoluble organic pollutants by turbidity.

实验结果表明：用浊度衡量老龄垃圾渗滤液非溶解态有机物的含量是合理的；垃圾渗滤液中非溶解态有机物对铁促电解去除COD的效率有显著影响。

Due to the cathode oxidizability and electrolyte instability, some primary reactions, such as electrolyte decomposition, cathode materials dissolution and self-heating redox reaction, arised at the cathode/electrolytes interface in Li-ion batteries, which deteriorated the electrochemical properties and safety of the batteries.

锂离子电池中的正极/电解液界面反应：电解液的氧化分解、正极材料腐蚀溶解及正极材料的自热氧化还原反应等，均能对电池的电化学性能和安全特性产生不良影响。

The effects of current density, H2SO4 concentration and electrolyzing time, temperature and patterns on electrochemical dissolution are investigated.

研究了电流密度、硫酸浓度、电解液温度、电解时间及电解方式等对电化学溶解的影响。

The copper-bearing alloy phase is solution when react with electrolyte forming the cavity while the anodic oxidation proceeding, rest of the alloy forming island in the cavity.

孔洞是由于在进行阳极氧化时含铜合金相与电解液发生反应溶解形成的，其中未溶解的在氧化时形成孔洞中间的岛屿状物。

The zinc oxidation leaching ratio can reach 86.73% in 96h. The oxidation mechanisms of zinc sulphide concentrate in different suspension electrolysis solution are almost same. However, the exchange current density in the process of oxidation is low and it will quicken electrochemical oxidation with the increasement of temperature.

通过实验分析得出：硫化锌矿在不同悬浮电解溶液中都能够被氧化，但有较大的差别，在硫酸锌、硫酸铵和硫酸的悬浮电解液中，矿物明显被氧化而溶解进入悬浮液中，氧化速度比较快，锌的氧化溶出率在96h的时间内达到86.73％。

We put zinc sulphide mine into different sulphate system and analyzed polarization curve about anodic oxidation.we found that the mine was oxidized effectively and the rapid oxidation happened when we adopted the zinc sulphide ore suspension electrolyte which contained ZnSO_4,(NH_4)_2SO_4 and H_2SO_4. This system was suffice to product metal zinc industrially. The appropriate suspension electrolyte composition consisted of zinc 90～130g/l,(NH_4)_2SO_430～50g/l, H_2SO_430～50g/l, suspension electrolysis temperature 50℃, anodic oxidation potentiometer 0.6～0.8V.

研究了硫化锌矿在不同的硫酸盐体系中的溶解，通过阳极氧化极化曲线进行分析，得出当以硫酸锌、硫酸铵和硫酸作为硫化锌矿悬浮电解液时，矿物能够有效地被氧化，氧化速度最快，能满足工业上生产金属锌的要求，并且合适的悬浮电解液组成为：锌90～130g/l，硫酸铵30～50g/l，硫酸30～50g/l，悬浮电解温度40～50℃，阳极氧化电位0.6～0.8V。

Because of the disadvantages in the electrolysis of rare earth metals, a new kind of electrode material called non-carbon anode is studied, and the corrosion mechanism is reseached.

针对稀土金属Nd的氟化物体系熔盐电解中石墨阳极所存在的一系列不足，研制了一种新型的电极材料，称其为非碳阳极；并对其在电解过程中的腐蚀机理进行了较详细的探讨，提出了还原反应、氧化反应、电解质渗透、电极组分溶解、析氧膨胀等几种可能的腐蚀原因。

electrodeposit：电镀

electrodeplating 电解溶解 | electrodeposit 电镀 | electrodeposition 电镀

electrolytic polishing：电解抛光

4 电解拋光(Electrolytic Polishing) 所谓电解拋光,即是将工件放置阳极,于电解液中通电,在适当操作参数下,使工件发生电解反应(亦称反电镀),工件表面而因电场集中效应而产生溶解作用,因而可达成工件表面平坦与光泽化之加工技术.

galvanic cell：电池

水气侵入时在相同导体金属间会引发电解反应(Electrolytic Reaction),使阳极金属溶解,阴极金属产生镀著;在不同导体金属间,水气会引发电池(Galvanic Cell)反应而产生腐蚀,这些反应都会造成IC元件的劣化与损坏.电子构装制程使用了各式各样的材料,

anodic removing：电解加工

anodic protection 阳极保护 | anodic removing 电解加工 | anodic solution 阳极溶解

zincate：锌酸盐

可由氢氧化锌溶解于过量碱中生成,其典型制备方法如下:锌酸盐(zincate)是指包含锌酸根离子ZnO2(2-)的盐类. 锌酸盐溶于水,溶液呈碱性,可用作碱性镀锌的电解液. 锌酸盐极易潮解,在空气中迅速吸收水分和二氧化碳,生成氢氧化锌.

electrodissolution：电解溶解 电溶解

electro-dissociationaryvacuum-gauge电离真空计 | electrodissolution电解溶解 电溶解 | electrodissolver电解溶解器

electrodissolution：电解溶解

electrodispersion | 电分散作用 | electrodissolution | 电解溶解 | electrodissolvent | 电解溶解剂