Siberian Federal University

The effect of temperature and duration of calcination of single-phase samples of hematite with the α-Fe2O3 structure on the oxidizing ability with respect to hydrogen in the temperature-programmed reaction mode in the temperature range of 40–900 °C was studied. It is shown that the calcination temperature is a significant factor affecting the reactivity of lattice oxygen in the oxidation of hydrogen. Samples of α-Fe2O3, calcined at 800–900 °C, show the highest activity, the process of α-Fe2O3 reduction in these samples proceeds through the stage of reduction to magnetite, followed by complete reduction to metal through the combination of reduction stages of oxides. The calcination of α-Fe2O3 samples at 1000–1100 °C leads to a significant decrease in the oxidizing ability, the α-Fe2O3 reduction initiates at temperatures 50–100 °C higher, proceeds without separating individual reduction stages of oxide, there is no complete reduction of α-Fe2O3 under the studied conditions. It has been established that with an increase in the calcination temperature of the hematite samples, the X‑ray density of α-Fe2O3 increases, which indicates a decrease in the degree of crystal lattice disorder and an increase in the binding energy of lattice oxygen and manifests itself in a significant decrease in the reactivity of α-Fe2O3 in the oxidation of hydrogen