Effects of grain size and grain boundary on critical current density of high T(sub c) superconducting oxides
Abstract
By means of adding impurity elements in high T sub c oxides, the effects were studied of grain size and grain boundary on the critical current density of the following systems: YBa2Cu3O(7-y) and Bi-Pr-Sr-Ca-Cu-O. In order to only change the microstructure instead of the superconductivity of the grains in the samples, the impurity elements were added into the systems in terms of the methods like this: (1) substituting Y with the lanthanide except Pr, Ce, and Tb in YBa2Cu3O(7-y) system to finning down grains in the samples, therefore, the effect can be investigated of the grain size on the critical current density of 1:2:3 compounds; (2) mixing the high T sub c oxides with the metal elements, such as Ag, according to the composition of (high T sub c oxide)1-xAgx to metallize the grain boundaries in the samples, studying the effect of the electric conductivity of the grain boundaries on the critical current density; (3) adding SiO2, PbO2, and SnO2 into the high T sub c oxide to form impurity phases in the grain boundaries, trying to find out the effects of the impurity phases or metalloid grain boundaries on the critical current density of the high T sub c superconductors. The experimental results indicate that in the case of of the presence of the metalloid grain boundaries finning down grains fails to enhance the j sub c, but restrains it strongly, the granular high T sub c superconductors with the small size grains coupled weakly is always the low j sub c system.
- Publication:
-
AMSAHTS 1990: Advances in Materials Science and Applications of High Temperature Superconductors
- Pub Date:
- April 1990
- Bibcode:
- 1990amsa.nasa...77Z
- Keywords:
-
- Copper Oxides;
- Current Density;
- Grain Boundaries;
- Grain Size;
- High Temperature Superconductors;
- Impurities;
- Microstructure;
- Barium Oxides;
- Electrical Resistivity;
- Metalloids;
- Silicon Dioxide;
- Superconductivity;
- Yttrium Oxides;
- Solid-State Physics