High-temperature instability of artificial cuprorivaite: a study using thermal analysis, X-ray powder diffractometry and polarized light microscopy

Abstract

CaCuSi4O10 powder was studied by differential scanning calorimetry and thermogravimetry methods in the range from room temperature to 1450\,C at heating and cooling rates of 20\,C/min. The process of decomposition of cuprorivaite, the composition and transformations of its decomposition products during successive heat treatments were also studied by powder X-ray diffraction and polarization optical microscopy techniques. It was found that CaCuSi4O10 starts to decompose by incongruent melting at a temperature of about 1020\,C, with the minimum of the endothermic DSC peak associated with this process being at 1064.4\,C. CaCuSi4O10 decomposes irreversibly and subsequent cyclic annealings up to a temperature of 1450\,C at heating and cooling rates of 20\,C/min do not cause its re-synthesis. CaCuSi4O10 transforms into a two-phase system consisting of acicular crystals of monoclinic tridymite fused with green glass with the composition CuO\,-\,Cu2O\,-\,CaO\,-\,SiO2, with the weight ratio of tridymite to glass being about 12:13, as a result of two successive annealings up to the temperature of 1450\,C.