ISSN 1608-4039 (Print)
ISSN 1680-9505 (Online)


For citation:

Kolosnitsyn V. S., Karaseva E. V., Amineva N. A., Danilenko V. N. Effect of synthesis conditions on electrochemical, electrophysical and structural characteristics of lithium cobalt oxide. Electrochemical Energetics, 2001, vol. 1, iss. 1, pp. 55-?.

This is an open access article distributed under the terms of Creative Commons Attribution 4.0 International License (CC-BY 4.0).
Language: 
Russian
Article type: 
Article

Effect of synthesis conditions on electrochemical, electrophysical and structural characteristics of lithium cobalt oxide

Autors: 
Kolosnitsyn Vladimir Sergeevich, Institute of Organic Chemistry of the Ufa RAS Scientific Center
Karaseva Elena Vladimirovna, Institute of Organic Chemistry of the Ufa RAS Scientific Center
Amineva N. A., Institute of Organic Chemistry of the Ufa RAS Scientific Center
Danilenko V. N., Institute of Problems of Superplasticity of Metals of RAS
Abstract: 

The processes of thermodestruction of lithium and cobalt oxides and their mixtures have been studied. The studies using the IR-spectroscopy as well thermogravimetric analysis showed, that during the initial stage of heating the mixtures of lithium and cobalt acetates the double salts form, and only then their thermodestruction proceeds. Using the methods of complexonometric and iodometric titration the change of oxidative – reductive state of cobalt during the thermodestruction process has been studied, it has been found, that the increase in synthesis temperature leads to the decrease in the oxidation degree of cobalt. The phase composition as well electrochemical properties of materials obtained have been studied using the methods of X-ray phase analysis, scanning electron microscope and chronopotentiometry. It was shown, that the formation of complex cobalt oxides starts at enough low temperatures (350°C). But electrochemical capacity of these products is not high due to a low degree of crystallinity. Products obtained at 750°C possess the highest electrochemical capacity.