Journal
JOURNAL OF POWER SOURCES
Volume 195, Issue 21, Pages 7391-7396Publisher
ELSEVIER
DOI: 10.1016/j.jpowsour.2010.06.004
Keywords
Lithium content; Cathode; High power; Lithium-ion batteries; Cycling
Funding
- U.S-DOD-ARO-Electrochemistry and Advanced Energy Conversion Division [W911NF-08-C-0415, 52322-CH-H (BOBBA)]
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Layered Li1+xNi0.30Co0.30Mn0.40O2 (x=0, 0.05, 0.10, 0.15) materials have been synthesized using citric acid assisted sol-gel method. The materials with excess lithium showed distinct differences in the structure and the charge and discharge characteristics. The rate capability tests were performed and compared on Li1+xNi0.30Co0.30Mn0.40O2 (x = 0, 0.05, 0.10, 0.15) cathode materials. Among these materials, Li1.10Ni0.30Co0.30Mn0.40O2 cathode demonstrated higher discharge capacity than that of the other cathodes. Upon extended cycling at 1C and 8C, Li1+xNi0.30Co0.30Mn0.40O2 showed better capacity retention when compared to other materials with different lithium content. Li1.10Ni0.30Co0.30Mn0.40O2 exhibited 93 and 90% capacity retention where as Li1.05Ni0.30Co0.30Mn0.40O2, Li1.15Ni0.30Co0.30Mn0.40O2, and Li1.00Ni0.30Co0.30Mn0.40O2 exhibited only 84, 71, and 63% (at 1C), and 79, 66 and 40% (at 10C) capacity retention, respectively, after 40 cycles. The enhanced high rate cycleability of Li1.10Ni0.30Co0.30Mn0.40O2 cathode is attributed to the improved structural stability due to the formation of appropriate amount of Li2MnO3-like domains in the transition metal layer and decreased Li/Ni disorder (i.e., Ni content in the Li layer). (C) 2010 Elsevier B.V. All rights reserved.
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