Paper Titles

Effect of Sodium-Based Slag Treatment on the Distribution of Impurities in Metallurgical Grade Silicon
p.949

Maximized On-Demand Hydrogen Generator Design
p.954

Purification of Silicon by Solvent Refining with Si-Sn Alloy
p.962

Studies on the Electrochemical Behavior of Sio/C Anode Materials by AC Impedance Method
p.967

Summarize the Studies on Improving the Electrochemical Performance of Spinel LiMn₂O₄
p.971

Temperature Distribution of Multi-Crystalline Silicon Ingots in the Directional Solidification Process
p.977

Cathode Material Li [Li_0.2 Mn_0.44Ni_0.18Co_0.18]O₂ Synthesized by Molten Salt Method
p.981

Fabrication of Micro DMFC Stack Using MEMS Technology
p.985

Mathematical Modeling of a DMFC Cathode with a Double Catalyst Layered Structure Membrane Electrode Assemblies
p.989

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 690-693Summarize the Studies on Improving the...

Summarize the Studies on Improving the Electrochemical Performance of Spinel LiMn₂O₄

Article Preview

Abstract:

Many studies show spinel LiMn2O4 is one of the most promising cathode materials for lithium ion batteries. At present, urgent need is that capacity attenuation in the process of charge / discharge and cycle stability at high temperature are developed. The methods can be classified into bulk doped, surface coated and nanometer particles. Research progress about improving the electrochemical performance of spinel LiMn2O4 is summarized and further research trend is pointed out in this paper.

You might also be interested in these eBooks

Materials Design, Processing and Applications

Info:

Periodical:

Advanced Materials Research (Volumes 690-693)

Pages:

971-976

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.690-693.971

Citation:

Cite this paper

Online since:

May 2013

Authors:

Fu Li Wang, Hong Dan Xue, Ke Wang, Pu Liu, Yong Qing Bai

Keywords:

Bulk Doped, Nanometer Particle, Spinel LiMn₂O₄, Surface Coated

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2013 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] Yingchao Chen. High power type lithium manganate anode material preparation and doping modification research[D]. National University of Defense Technology, 2011,7-15. (In chinese)

[2] Zhanxu Yang, Qingdong Qiao, Xiaoxue Kang. Modern Chemical Industry, 2012,32(1):14-18. (In chinese)

[3] Zhaochu He, Xinjuan Zhuang, Aiguo Peng. Fine Chemical Intermediates, 2010,40(1):7-11. (In chinese)

[4] Ping Li, Qi Li, Hongzhi Xu, et al. Inorganic Chemicals Industry, 2008,40(1):1-4. (In chinese)

[5] Ying Liang, Mumin Rao, Zongping Cai, et al. Chinese battery industry, 2009,14(1): 69-72. (In chinese)

[6] Chao Wang, Xingquan Liu, Hongji Liu, et al. Electronic components and materials, 2012,31(6):22-27. (In chinese)

[7] Zhixing Wang, Xinhai Li, Huajun Guo, et al. Transactions of Nonferrous Metals Society of China, 2008,18(Special1):279-283. (In chinese)

[8] S Guo, Xiangming He, Weihua Pu, et al. Journal of the Chinese Rare Earths Society, 2006,24(suppl):16-20. (In chinese)

[9] Hailang Zhang, Jing An. Journal of Functional Materials, 2009,40(sup.):507-508. (In chinese)

[10] Tu J, Zhao X B, Zhuang D G,et al. Physics B, 2006,382:129-134.

[11] Changjiu Liu, Jichun Li, Lingying Yi, et al. Journal of the Chinese Rare Earths Society, 2007,25(3):280-283. (In chinese)

[12] Shuting Yang, Junhua Jia, Liqing Zheng, et al. Journal of the Chinese Rare Earths Society, 2003,21(4):413-416. (In chinese)

[13] Chunli Zhang, Xuehai Ye, Xiaobo Zhang, et al. Inorganic Chemicals Industry, 2012,44(6):61-62. (In chinese)

[14] Ohzuku T, Takeda S, Iwanaga M. J Power SOURCES, 1999,81-82:90-94.

[15] Wu C,Wu F,Chen L Q,Huang X J. Solid State Ionics, 2002,152-153:327-334.

[16] Son J T, Kim H G, Park Y J, Electrochim. Acta, 2004,50:453-459.

[17] He B, Bao S, Liang Y, et al. Journal of Solid State Chamistry, 2005,178:897-901.

[18] Molenda M, Dziembaj R, Podstawka E, et al. Journal of Power Source, 2007,174:613-618.

[19] Molenda M, Dziembaj R, Podstawka Z, et al. Solid State Ionice, 2008,179:88-92.

[20] Yihong Qin, Shangde Ma, Yunhe Zhang. Chinese Journal of Power Sources, 2008,32(5):293-295. (In chinese)

[21] LU Xinghe, ZHANG Guangqing, MA Nan, et al. Acta Scientiarum Naturalium Universitis Sunyatsem, 2009,48(Sup.2):73-75.

[22] Zhiyuan Tang, Xinghe Lu, Na Zang. Chinese Journal of Inorganic Chemisty, 2005,21(9):1427-1432. (In chinese)

[23] Hongfu Cai, Hailang Zhang, Junfang Wang. Applied Chemical Industry, 2010,39(11):1653-1657. (In chinese)

[24] Peizhi Li, Jia Mei, Shengwen Zhong,et al. Chinese Battery Industry, 2006,11(2):135-138. (In chinese)

[25] Hong Gao, Qingfeng Yang. Non-ferrous Mining and Metallurgy, 2005,21(3):31-35. (In chinese)

[26] Shang Li, Wuxing Zhang, Ze Yang,et al. Material Review, 2011,25(6):53-57. (In chinese)

[27] Gerbaldi C, Meligrana G, Bodoardo S, et al. J Power Sources, 2007,174(2):501.

[28] Jinlian Liu, Xianming Wu, Faren Mai, et al. Rare Metals, 2012,36(3):433-438. (In chinese)

[29] Gnanaraj J S, Pol V G, Gedanken A, et al. Electrochemistry Communications, 2003,5(11):940.

[30] Bing Sun, Jincheng Liu, Maosen Pan, et al. Zhangjiagang 2009.10.23-26 The third China energy storage and power battery and key materials of academic research and exchange of Technology, 41-42. (In chinese)

[31] Hong Wang, Lunyu Zhu, Mingcai Chen. Chinese Journal of Power Sources, 2007,31(3): 239-241. (In chinese)

[32] Yifeng Zhou, Wangyan Nie, Chunhua Chen, et al. Journal of Functional Materials, 2006,37(9):1381-1385. (In chinese)

[33] Jiang C H, Hosono E, Zhou H S. Nano Today, 2006,1:28-33.