Abstract
Intercalation cathode materials belonging to the 4-volt class electrodes, lithiated cobalt oxide LiCoO2 and lithiated nickel cobalt oxide LiCo0.4Ni0.6O2, were synthesized by sol-gel technique. The structural characteristics of the compounds were studied using XRD, FTIR and DSC. The compounds were used as cathode materials for assembling rechargeable lithium-batteries and their electrochemical performances were studied. The potentiostat and galvanostat techniques were used to determine the electrochemical characteristics. The irreversible capacity loss of LiCoO2 during the first charge-discharge is about 20% and for LiCo0.4Ni0.6O2 is about 90% for two different current rates of 5 and 10 A kg -1 . The overall electrochemical capacity of LiCo0.4Ni0.6O2 has been drastically reduced due to the s-block or p-block metal substitution. Also the un-reacted materials remained as impurities gave a very poor cycleability. However more stable charge-discharge performances have been observed for LiCoO2 at different current rates. Differences and similarities between these two cathode materials in batteries are also discussed. The Li-ion batteries were assembled using the sol-gel synthesized cathode materials, natural untreated vein graphite of Sri Lanka as the anode material and 1 M LiPF6 in EC/DMC as liquid electrolyte, and their performances were tested.
Highlights
Lithium cobalt oxide (LiCoO2) is extensively used as a cathode material in commercially available Li-ion batteries due to its high energy density and good cycle-life performances.N.W.B
The aim of the present work is to study the structural and electrochemical properties of LiCoO2 and LiCo0.4Ni0.6O2 synthesized by sol-gel method and testing the performances in the 4-volts class Li-ion batteries
Nitrates of lithium and cobalt were weighed according to cationic ratio to synthesis of LiCoO2
Summary
Lithium cobalt oxide (LiCoO2) is extensively used as a cathode material in commercially available Li-ion batteries due to its high energy density and good cycle-life performances. N.W.B. Balasooriya and P.W.S.K. Bandaranayake / Sri Lankan Journal of Physics, Vol. (2007) 47-58. Its major drawbacks are high price and toxicity of cobalt. To overcome these problems, various cathode materials without cobalt, such as LiMxNiyO2 where M is one of the transition or alkaline earth metals have been used. The battery performances of LiCoO2 are superior to other cathode materials. The present study was focused to reduce the cost and toxicity of Co by replacing 60% of Co by a cheaper and non-toxic element Ni
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