Comparative effect of crystallite size and calcination temperature on the thermal stability of spinel type metal oxide

Abstract

The nanostructured material zinc chromite, zinc manganite, zinc ferrite and zinc cobaltile were synthesized via the thermal reaction of zinc acetate and metal acetylacetonate, stoichiometric ratios of Zn/Metal equal to 0.5, in 1,4-butanediol at 300 ํC for 2 hours under autogenous pressure with different reaction heating rate of 2.5 and 1.0 ํC/min. Zinc chromite and zinc ferrite were directly formed after glycothermal reaction, while zinc manganite and zinc cobaltile which were formed via an undetermined intermediate phase had to be calcined at a desired temperature before forming spinel phase. It was found that the reaction heating rate affected significantly on the crystallite size of the as-synthesized products. The crystallite size of the as-synthesized products observed by TEM was close to that examined by XRD. This suggested that each particle was a single crystal. After calcination at various temperatures, the results indicated that the thermal stability of the spinel type metal oxides lied in the correlation of, ZnCr2O4>ZnMn2O4>ZnFe2O4~ZnCo2O4 The thermal stability of the product was designed from the ratio of the crystallite size of the product after calcined (d) to the crystallite size of the as-synthesized sample (d0). Teh spinel structure, before and after calcination, revealed the same performance even after calcined at high temperature