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References (14)
-
H. Kawai, M. Nagata, H. Tukamoto, A. West (1999)
High-voltage lithium cathode materialsJournal of Power Sources, 81
-
M. and, D. Aurbach (2004)
Impedance of a Single Intercalation Particle and of Non-Homogeneous, Multilayered Porous Composite Electrodes for Li-ion BatteriesJournal of Physical Chemistry B, 108
-
脇原 将孝, 山本 治 (1998)
Lithium ion batteries : fundamentals and performance -
R. Gummow, A. Kock, M. Thackeray (1994)
Improved capacity retention in rechargeable 4 V lithium/lithium- manganese oxide (spinel) cellsSolid State Ionics, 69
-
Y. Shao-horn, R. Middaugh (2001)
Redox reactions of cobalt, aluminum and titanium substituted lithium manganese spinel compounds in lithium cellsSolid State Ionics, 139
-
P. Bruce, A. Armstrong, Haitao Huang (1997)
New and optimised lithium manganese oxide cathodes for rechargeable lithium batteriesJournal of Power Sources, 68
-
T. Ohzuku, S. Takeda, Masato Iwanaga (1999)
Solid-state redox potentials for Li[Me1/2Mn3/2]O4 (Me: 3d-transition metal) having spinel-framework structures: a series of 5 volt materials for advanced lithium-ion batteriesJournal of Power Sources, 81
-
A. Kock, E. Ferg, R. Gummow (1998)
The effect of multivalent cation dopants on lithium manganese spinel cathodesJournal of Power Sources, 70
-
Sun‐Ho Kang, J. Goodenough (2000)
Li[Mn2]O4 spinel cathode material showing no capacity fading in the 3 V rangeJournal of The Electrochemical Society, 147
-
Ru‐Shi Liu, C. Shen (2003)
Structural and electrochemical study of cobalt doped LiMn2O4 spinelsSolid State Ionics, 157
-
J. Meyers, M. Doyle, R. Darling, J. Newman (2000)
The Impedance Response of a Porous Electrode Composed of Intercalation ParticlesJournal of The Electrochemical Society, 147
-
L. Hernán, J. Morales, L. Sánchez, Jesús Santos (1999)
Use of Li–M–Mn–O [M=Co, Cr, Ti] spinels prepared by a sol-gel method as cathodes in high-voltage lithium batteriesSolid State Ionics, 118
-
K. Amine, H. Tukamoto, H. Yasuda, Y. Fujita (1997)
Preparation and electrochemical investigation of LiMn2 − xMexO4 (Me: Ni, Fe, and x = 0.5, 1) cathode materials for secondary lithium batteriesJournal of Power Sources, 68
-
R. Alcántara, M. Jaraba, P. Lavela, J. Tirado (2002)
Optimizing preparation conditions for 5 V electrode performance, and structural changes in Li1−xNi0.5Mn1.5O4 spinelElectrochimica Acta, 47
- Publisher
- Springer Journals
- Copyright
- Copyright © 2006 by Springer-Verlag
- Subject
- Chemistry; Electrochemistry; Renewable and Green Energy; Optical and Electronic Materials; Condensed Matter Physics; Energy Storage
- ISSN
- 0947-7047
- eISSN
- 1862-0760
- DOI
- 10.1007/s11581-006-0045-z
- Publisher site
- See Article on Publisher Site
Abstract
The introduction of Co, Al, and Ti into LiMn2O4 cathode powders has been studied in this work. The substitution of 25% Mn with either of these metals is expected to improve the cycle ability of the cathode, while the Jahn–Teller effect is suppressed. The solid-state reaction method is used in order to produce the cathode materials, which are prepared at 750 or 800 °C. The materials are characterized by X-ray data and, electrochemically, by galvanostatic cycling at the 4-V range. Their capacity fading behavior is evaluated, and a further investigation into cycling at a higher voltage range is also presented.
Journal
Ionics – Springer Journals
Published: Sep 19, 2006