Abstract
Nanocomposites SnO&sub2;/SiO&sub2; with a silicon content of [Si]/([Sn] + [Si]) = 3/86 mol.% were obtained by the hydrothermal method. The composition and microstructure of the samples were characterized by EDX, XRD, HRTEM and single-point Brunauer-Emmet-Teller (BET) methods. The surface sites were investigated using thermal analysis, FTIR and XPS. It is shown that the insertion of silicon dioxide up to the value of [Si]/([Sn] + [Si]) = 19 mol.% stabilizes the growth of SnO&sub2; nanoparticles during high-temperature annealing, which makes it possible to obtain sensor materials operating stably at different temperature conditions. The sensor properties of SnO&sub2; and SnO&sub2;/SiO&sub2; nanocomposites were studied by in situ conductivity measurements in the presence of 10-200 ppm CO in dry and humid air in the temperature range of 150-400 °C. It was found that SnO&sub2;/SiO&sub2; nanocomposites are more sensitive to CO in humid air as compared to pure SnO&sub2;, and the sample with silicon content [Si]/([Sn] + [Si]) = 13 mol.% is resistant to changes in relative air humidity (RH = 4%-65%) in the whole temperature range, which makes it a promising sensor material for detecting CO in real conditions. The results are discussed in terms of the changes in the composition of surface-active groups, which alters the reactivity of the obtained materials.