首页> 美国政府科技报告 >Development of High Conductivity Lithium-Ion Electrolytes for Low Temperature Cell Applications

【24h】

Development of High Conductivity Lithium-Ion Electrolytes for Low Temperature Cell Applications

机译：用于低温电池应用的高电导率锂离子电解质的开发

获取原文

页面导航

摘要
著录项
相似文献
相关主题

摘要

NASA has continued interest in developing power sources which are capable of operating at low temperatures (-20 C and below) to enable future missions, such as the Mars Rover and Lander. Thus, under a program sponsored by the Mars Exploration Program, we have been involved in developing Li-ion batteries with improved low temperature performance. To accomplish this task, the focus of the research has been upon the development of advanced electrolyte systems with improved low temperature properties. This had led to the identification of a carbonate-based electrolyte, consisting of 1.0 M LiPF6 in EC + DEC + DMC (33:33:34), which has been shown to have excellent performance at -20 C in Li-ion AA-size prototype cells. Other groups are also actively engaged in developing electrolytes which can result in improved low temperature performance of Li-ion cells, including Polystor, Yardney, and Covalent. In addition to developing cells capable of operation at -20 C, there is continued interest in systems which can successfully operate at even lower temperatures (less than -30 C) and at high discharge rates (greater than C/2). Thus, we are currently focusing upon developing advanced electrolytes which are highly conductive at low temperatures and will result in cells capable of operation at -40 C. One approach to improve the low temperature conductivity of ethylene carbonate-based electrolytes involves adding co-solvents which will decrease the viscosity and extend the liquid range. Candidate solvent additives include formates, acetates, cyclic and aliphatic ethers, lactones, as well as other carbonates. Using this approach, we have prepared a number of electrolytes which contain methyl formate (MF), methyl acetate (MA), ethyl acetate (EA), ethyl proprionate (EP), and 1,2-dimethoxyethane (DME), some of which have been characterized and reported. Other groups have also reported electrolytes based on mixtures of carbonates and acetates. In the present study, electrolytes which have been identified to have good low temperature conductivity and stability were incorporated into lithium-graphite cells for evaluation. Using various electrochemical methods, including ac impedence and DC micropolarization techniques, the film formation characteristics of graphite electrodes in contact with various lectrolyte formulations was investigated.

著录项

作者
Smart, M. C.; Ratnakumar, B. V.; Surampudi, S.;
展开▼
作者单位

展开▼
年度 1998
页码 1-5
总页数 5
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Electrolytes; Lithium; Low temperature; Electrochemical cells; Conductivity; Metal ions; Graphite; Ion temperature; Methyl compounds; Electrical impedance; Linear polarization;

机译：电解质;锂;低温;电化学电池;电导率;金属离子;石墨;离子温度;甲基化合物;电阻抗;线性极化;

相似文献

外文文献
中文文献
专利

1. Optimization of EC-based multi-solvent electrolytes for low temperature applications of lithium-ion batteries [J] . L. F. Xiao, Y. L. Cao, X. P. Ai, Electrochimica Acta . 2004,第27期

机译：锂离子电池低温应用中基于EC的多溶剂电解质的优化
2. Electrical conductivity of M~(2+)-doped (M = Mg, Ca, Sr, Ba) cerium pyrophosphate-based composite electrolytes for low-temperature proton conducting electrolyte fuel cells [J] . Bhupendra Singh, Sang-Yun Jeon, Ha-Ni Im Journal of Alloys and Compounds: An Interdisciplinary Journal of Materials Science and Solid-state Chemistry and Physics . 2013,第Null期

机译：低温质子传导电解质燃料电池用M〜（2+）掺杂（M = Mg，Ca，Sr，Ba）焦磷酸铈基复合电解质的电导率
3. Application of nonflammable electrolyte with room temperature ionic liquids (RTILs) for lithium-ion cells [J] . Hiroe Nakagawa, Yukiko Fujino, Suguru Kozono, Journal of power sources . 2007,第2期

机译：室温离子液体（RTIL）不可燃电解质在锂离子电池中的应用
4. Development of High Conductivity Lithium-ion Electrolytes for Low Temperature Cell Applications [C] . M.C. Smart, B.V. Ratnakumar, S. Surampudi Power sources conference . 1998

机译：用于低温电池应用的高电导率锂离子电解质的开发
5. Enhancement of ionic conductivity of solid and gel polymer electrolytes by nanoconfinement of electrolyte materials in alumina interpenetrating networks for room temperature lithium ion nanobattery applications. [D] . Jayasekara, Indumini U. 2016

机译：在室温互穿的锂离子纳米电池应用中，通过氧化铝互穿网络中电解质材料的纳米约束，可以提高固体和凝胶聚合物电解质的离子电导率。
6. Flexible and Self-Healing Aqueous Supercapacitors for Low Temperature Applications: Polyampholyte Gel Electrolytes with Biochar Electrodes [O] . Xinda Li, Li Liu, Xianzong Wang, -1

机译：适用于低温应用的灵活的自修复水性超级电容器：带有生物炭电极的聚两性电解质凝胶电解质
7. New electrolytes and electrolyte additives to improve the low temperature performance of lithium-ion batteries [O] . Yang, Xiao-Qing 2008

机译：新型电解质和电解质添加剂可改善锂离子电池的低温性能

Development of High Conductivity Lithium-Ion Electrolytes for Low Temperature Cell Applications

摘要

著录项

相似文献

相关主题

期刊订阅