Evolution of the microstructure during high-temperature creep and oxygenation in directionally solidified YBa2Cu3O7-x

Abstract

Abstract The microstructure of YBa2Cu3O7−x −Y2BaCuO5 melt-textured composities deformed in the secondary and tertiary creep regimes has been investigated by transmission electron microscopy. The high density of Y2BaCuO5 precipitates plays an important role in the microstructural development as pinning sites for gliding dislocations. In the secondary regime, trapped dislocations are dissociated, leaving a stacking fault with displacement vector [½—δ 0 ⅓]. A second stacking fault, ⅙〈301〉, is typically associated with the former stacking fault. At this stage, the deformation microstructure is dominated by diffusive processes between precipitates interconnected by the trapped dislocations. In the tertiary stage, dislocation multiplication is the main factor controlling the microstructure, which is characterized by a dramatic increase in the density of perfect dislocations with Burgers vectors 〈100〉 and 〈110〉. Since deformation is performed above the orthohombic-to-tetragonal transition temperature, the samples need to be oxygenated in order to achieve the superconducting phase. We have found that this oxygenation step, performed at 450°C, induces severe modifications of the as-deformed microstructure.