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Experimental investigations on a novel thermoelectric material (Na x CoO2)

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Thermoelectric (TE) devices can be used reversely as a heat pump for refrigeration (heat management) and mostly oxide materials are used in these devices. Metal oxide-based TE materials possess several… Click to show full abstract

Thermoelectric (TE) devices can be used reversely as a heat pump for refrigeration (heat management) and mostly oxide materials are used in these devices. Metal oxide-based TE materials possess several advantages compared to metal chalcogenides. These materials can be employed, since they are environment-friendly and cost-effective. TE performance can be easily tuned and this can be achieved through composition and structure. In the present work, Na0.77CoO2/nano Co3O4 composites are chosen. Although Na x CoO2 possesses superior TE performance to other oxide-based materials, its application has been limited due to its instability in air. It decomposes into the insulating Co(OH)2 and/or CoCO3 by absorbing moisture and/or CO2 from the ambient environment. Upon heating, both Co(OH)2 and CoCO3 decompose further into the insulating Co3O4 and CoO. Therefore, it is important to explore the chemical stability of Na x CoO2. This study analyses the reasons for the chemical instability of Na x CoO2 without impairing its TE properties. Na0.77 CoO2 was prepared by the solid-state synthesis method and the single phase was observed in XRD. Again XRD was taken after 15 days, to analyse the stability of the prepared sample. The peaks corresponding to Na0.77CoO2 disappeared. The reasons for this instability were analysed and possible solutions are suggested.

Keywords: coo2; experimental investigations; investigations novel; thermoelectric material; novel thermoelectric; material coo2

Journal Title: International Journal of Ambient Energy
Year Published: 2019

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