A1 Refereed original research article in a scientific journal
Improving the Flux Pinning With Artificial BCO Nanodots and Correlated Dislocations in YBCO Films Grown on IBAD-MgO Based Template
Authors: Khan MZ, Zhao Y, Wu X, Jha R, Awana VPS, Huhtinen H, Paturi P
Publisher: IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
Publication year: 2019
Journal: IEEE Transactions on Applied Superconductivity
Journal name in source: IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY
Journal acronym: IEEE T APPL SUPERCON
Article number: ARTN 8002105
Volume: 29
Issue: 5
Number of pages: 5
ISSN: 1051-8223
eISSN: 1558-2515
DOI: https://doi.org/10.1109/TASC.2019.2897433
Abstract
To improve the performance of high-temperature superconductors in electrical power systems, a modified IBAD-MgO based template is used as a substrate for the growth of YBa2Cu3O6+x(YBCO) doped with various concentrations of BaCeO3 (BCO). The highest critical current density (J(c)) in a wide applied field and angular range is realized in the films doped with 2% and 4% BCO content. This is explained to arise from the optimized BCO dopant concentration, which helps to immobilize more vortices both in low and high field ranges. Besides the vortex pinning by randomly distributed BCO nanoparticles, the edge-type dislocations, mainly occurring due to the underlying IBAD-MgO based template, are also a main source of pinning the vortices as seen by the appearance of c-axis peak of J(c)(theta) in undoped and 2% doped films. The disappearance of c-peak in films doped with higher concentration can he qualitatively explained by the vortex path model, where the paths of the vortices arising because of high density of BCO particles disguise the columnar type pinning effect coming from the threading dislocations within the films. Therefore, the BCO nanodots can be used for improving the flux pinning besides the threading dislocations in YBCO films on metal substrates.
To improve the performance of high-temperature superconductors in electrical power systems, a modified IBAD-MgO based template is used as a substrate for the growth of YBa2Cu3O6+x(YBCO) doped with various concentrations of BaCeO3 (BCO). The highest critical current density (J(c)) in a wide applied field and angular range is realized in the films doped with 2% and 4% BCO content. This is explained to arise from the optimized BCO dopant concentration, which helps to immobilize more vortices both in low and high field ranges. Besides the vortex pinning by randomly distributed BCO nanoparticles, the edge-type dislocations, mainly occurring due to the underlying IBAD-MgO based template, are also a main source of pinning the vortices as seen by the appearance of c-axis peak of J(c)(theta) in undoped and 2% doped films. The disappearance of c-peak in films doped with higher concentration can he qualitatively explained by the vortex path model, where the paths of the vortices arising because of high density of BCO particles disguise the columnar type pinning effect coming from the threading dislocations within the films. Therefore, the BCO nanodots can be used for improving the flux pinning besides the threading dislocations in YBCO films on metal substrates.
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