Abstract
Synthesis and study of materials based on bismuth cerates and titanates were carried out. Complex oxides Bi(1.6)Y(0.4)Ti(2)O(7) were synthesized by the citrate route; Bi(2)Ce(2)O(7) and Bi(1.6)Y(0.4)Ce(2)O(7)-by the Pechini method. The structural characteristics of materials after conventional sintering at 500-1300 °C were studied. It is demonstrated that the formation of a pure pyrochlore phase, Bi(1.6)Y(0.4)Ti(2)O(7), occurs after high-temperature calcination. Complex oxides Bi(2)Ce(2)O(7) and Bi(1.6)Y(0.4)Ce(2)O(7) have a pyrochlore structure formed at low temperatures. Yttrium doping of bismuth cerate lowers the formation temperature of the pyrochlore phase. As a result of calcination at high temperatures, the pyrochlore phase transforms into the CeO(2)-like fluorite phase enriched by bismuth oxide. The influence of radiation-thermal sintering (RTS) conditions using e-beams was studied as well. In this case, dense ceramics are formed even at sufficiently low temperatures and short processing times. The transport characteristics of the obtained materials were studied. It has been shown that bismuth cerates have high oxygen conductivity. Conclusions are drawn about the oxygen diffusion mechanism for these systems. The materials studied are promising for use as oxygen-conducting layers in composite membranes.