Title :
Improving flux pinning at high fields in intermetallic superconductors: clues from MgB2 and MgCNi3
Author :
Cooley, Lance ; Song, Xueyan ; Larbalestier, David
Author_Institution :
Appl. Supercond. Center, Wisconsin Univ., Madison, WI, USA
fDate :
6/1/2003 12:00:00 AM
Abstract :
We discuss flux pinning and nanostructural analyzes of two intermetallic superconductors that exhibit substantial deviations from the usual flux-shear behavior. Kramer plots for a MgB2 thin film, which contained a substantial fraction of MgO nanoprecipitates, show an additional component that is attributed to core pinning by the precipitates. Also, polycrystalline MgCNi3 displays a crossover from flux-shear to core pinning behavior as the temperature is reduced. At the same time, the flux line core diameter becomes comparable to the length scales of nanoprecipitates found by high-resolution electron microscopy. Thus, both experiments suggest that flux shear, and its low-field pinning characteristic, can be exceeded by incorporating nanoprecipitates in an intermetallic superconductor. However, too many precipitates within the grain boundaries can block uniform current flow between grains.
Keywords :
electron microscopy; flux pinning; grain boundaries; magnesium alloys; magnesium compounds; nanostructured materials; nickel alloys; precipitation; superconducting thin films; Kramer plot; MgB2; MgB2 thin film; MgCNi3; MgO nanoprecipitate; core pinning; flux pinning; flux shear; grain boundary; high-resolution electron microscopy; intermetallic superconductor; nanostructural analysis; polycrystalline MgCNi3; Electrons; Flux pinning; Grain boundaries; Grain size; Intermetallic; Nanostructured materials; Pulsed laser deposition; Superconducting thin films; Superconductivity; Temperature;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2003.812225
