Lithium-ion batteries have two electrodes immersed in an electrically conductive solution, called an electrolyte.
锂离子电池有两个电极浸入在被称作电解质的导电溶液中。
Electrolyte was one of the key points which made rechargeable lithium ion batteries with high power and energy density, long cycling life and desirable safety.
电解质是制备高功率密度和高能量密度、长循环寿命和安全性能良好的锂离子电池的关键材料之一。
Based on the calculation results of these parameters, we can choose electrolyte functional composition of lithium ion battery.
根据对这几个参数的计算结果,可选择所需要的锂离子电池电解液功能组分。
Solid success: With a solid mixture of two polymers replacing the liquid electrolyte used in traditional lithium-ion cells (top), Seeo's batteries (right) can store more energy.
成果:用两种聚合物的固态混合物,取代传统锂电池(上)中的液态电解质,Seeo公司的这种电池(下)可存储更多的能量。
The three primary functional components of a lithium ion battery are the anode, cathode, and electrolyte, for which a variety of materials may be used.
锂离子电池的三个主要功能部分是阳极、阴极和电解液,当然还要使用其它各类材料。
The anode and cathode materials, electrolyte and its additives, structure of battery and manufacture process had important effect on the safety of Li-ion battery.
正负极材料、电解液及其添加剂、电池的结构以及制备工艺条件都对锂离子电池的安全性有重要的影响。
Electrode materials, electrolyte and separator are important parts of lithium-ion batteries, which can influence the performance of battery directly.
电极材料、电解质和隔膜是锂离子电池重要组成部分,直接影响电池的性能。
Electrolyte is one of the key materials of synthesis of lithium ion battery of high density of power, high density of energy, long circular life and good capability of security.
电解质是制备高功率密度、高能量密度、长循环寿命和安全性能良好的锂离子电池的关键材料之一。
Experiments showed that the absorption quantity of surfactant increases with the increase of electrolyte concentration and ion intensity.
实验表明:表面活性剂的吸附量随着电解质的浓度及离子强度的增加而增大;
The ionic conductivity of PEO-based electrolyte is related to the structure of polymer chain, concentration of ion temperature and plasticizer.
PEO基聚合物电解质中离子的运动能力与链的结构、离子浓度、温度、增塑剂等因素有关。
Depending on the choice of material for the anode, cathode, and electrolyte the voltage, capacity, life, and safety of a lithium ion battery can change dramatically.
根据阳极、阴极、和电解液材料的不同,锂离子电池的电压、容量、寿命、安全性会有很大的不同。
The initial efficiency of discharge-charge, resistance, cycle performance, voltage platform and low temperature performance of Li-ion batteries with different electrolyte was studied.
对使用不同电解液的电池的初始充放电效率、内阻、循环性能、电压平台、低温性能等进行了测试分析。
The methods of determining gold in ore, cyanide leaching solution, electrolyte and ion exchange resin in RIP are reviewed.
综述了树脂矿浆法提金工艺中的矿石、氰化浸出液、电解液和载金树脂中金的测定方法及应用。
The main performance, characteristics and the market prospect of polymer lithium ion batteries are introduced as well as the solid polymer electrolyte it adopted.
介绍了聚合物锂离子蓄电池的主要性能特点,采用的聚合物固体电解质体系和市场前景。
The space charge model, the fixed-charge model, the electrostatic and three-dimensional hindrance model, Donnan-steric pore model can be applied to characterize electrolyte and ion separation.
分离电解质和离子时包括空间电荷模型、固定电荷模型、静电阻碍模型和道南-细孔模型。
When voltage is applied in a first direction an ion bridge forms across through the electrolyte across electrodes making the resistor conductive.
当电压沿第一方向施加时,跨电极穿过电解质形成离子桥,使电阻器导电。
A lithium polymer battery is a type of lithium ion battery. Generally, the main difference is lithium ion polymer batteries contain a polymer electrolyte.
锂聚合物电池是锂离子电池的一种。一般来说,主要的区别是锂离子聚合物电池含有某种聚合物电解质。
Fast ion conductors (sometimes are named solid electrolyte) are a kind of solid material which ion conductivity can near or exceed liquid electrolyte.
快离子导体(有时又称固体电解质)是指离子电导率接近有时甚至超过盐溶液和电解质溶液的一类固态材料。
The shaped microporous article may also have the micropores filled with a sufficient quantity of ion conducting electrolyte to allow the membrane to function as an ion conductive membrane.
所述成形微孔制品的微孔也可用足量的离子传导电解质填充,使得所述膜用作离子传导膜。
As a research hotspot, amorphous solids electrolyte for lithium-ion secondary batteries has become one of the most active fields in condensed matter physics and an advanced part in material science.
锂离子二次电池非晶态电解质作为研究热点,同时也是凝聚态物理学中最为活跃的领域之一,并且成为材料科学的一个前沿部分。
Non-aqueous electrolyte secondary battery negative electrode material, making method, and lithium ion secondary battery.
非水电解质二次电池负极材料,制造方法,和锂离子二次电池。
The effects of hexamethyldisilazane(HMDS)to the stability of electrolyte and cycle performance of Li-ion battery were studied.
研究了六甲基二硅氮烷(HMDS)对电解液稳定性和锂离子电池循环性能的影响。
The high ion conductive solid electrolyte is obtained which is composed of the complex compound having zirconic acid compound, polyvinyl alcohol, and water.
获得了高离子电导率的固体电解质,其由一种含有锆酸化合物、聚乙烯醇和水的配位化合物组成。
Therefore, the study of oxygen ion conductor electrolyte nanometer multilayer film structure, electrical properties and stability has become an important research.
因此,研究纳米多层氧离子导体电解质薄膜结构、电学性能和稳定性已成为一个重要研究内容。
Various electrochemical systems are obtained each of which use the high ion conductive solid electrolyte.
获得了均使用高离子导电固体电解质的各种电化学体系。
Searching electrolyte low temperature co-solvent and investigating the effect of it on low temperature electrochemical performance of lithium ion batteries are the intentions of this research.
本课题的立意在于寻求锂离子电池电解液的低温共溶剂,并考察其对锂离子电池低温电化学性能的影响。
The invention can be applied to the preparation field of the lithium hexafluorophosphate in a lithium ion battery electrolyte.
本发明可应用于锂离子电池电解液中的六氟磷酸锂的制备领域。
Owing to the liquid state organic electrolyte is fixed in micro polymer network structure, polymer lithium ion cell in apparent dry state is prepared.
由于液态有机电解液固定于聚合物网络的微结构中,从而制得表观干态的聚合物锂离子电池。
The performance such as conductivity and electrochemical stability of common organic electrolyte of Li-ion batteries and general requirement for electrolyte were reviewed.
综述了锂离子电池常用有机电解液的电导率、电池学稳定性等性能及电池对电解液的一般要求。
The performance such as conductivity and electrochemical stability of common organic electrolyte of Li-ion batteries and general requirement for electrolyte were reviewed.
综述了锂离子电池常用有机电解液的电导率、电池学稳定性等性能及电池对电解液的一般要求。
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