Intragranular defects and Abrikosov–Josephson vortices in Bi-2223 bulk superconductors

The Abrikosov–Josephson (AJ) vortices that emerge at intragranular defects of Bi-2223 bulk superconductors are detected. The study is based on the combination of magnetic and transport characterizations with a brief theoretical formulation that allow estimating the minimum angle of the intragranular...

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Bibliographic Details
Published inJournal of materials science. Materials in electronics Vol. 28; no. 20; pp. 15246 - 15251
Main Authors Hernández-Wolpez, M., Cruz-García, A., Jardim, R. F., Muné, P.
Format Journal Article
LanguageEnglish
Published New York Springer US 01.10.2017
Springer Nature B.V
Subjects
Anisotropy
Bismuth strontium calcium copper oxide
Characterization and Evaluation of Materials
Chemistry and Materials Science
Critical field (superconductivity)
Crystal defects
Crystallites
Defects
Grains
Magnetic fields
Magnetic flux
Magnetism
Materials Science
Misalignment
Optical and Electronic Materials
Superconductors
Vortices
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Summary:The Abrikosov–Josephson (AJ) vortices that emerge at intragranular defects of Bi-2223 bulk superconductors are detected. The study is based on the combination of magnetic and transport characterizations with a brief theoretical formulation that allow estimating the minimum angle of the intragranular planar defects where the AJ vortices emerges for a given applied magnetic field. Measurements of magnetization versus applied magnetic field, M ( H a ) , in powder samples reveal that the intrinsic anisotropy effects of the grains in these materials suffer almost a complete attenuation due to their high shape anisotropy. In fact, powder samples behave as composed of isotropic grains with lower critical field ~80 Oe. However, a more detailed analysis of the quasi-linear part of these curves show that the penetration of the magnetic flux into intragranular defects occurs at similar values of applied magnetic fields than those reported in whiskers or well textured ceramics for their two main perpendicular directions which are lower values than ~80 Oe. Finally, taking into account a brief theoretical formulation, we have found that in the case of defects where the magnetic flux penetrates perpendicular to the c -axis of the crystallites (~30 Oe) approximately the stacking faults and defects with misorientation angles higher than ~14 ∘ can be the main causes of flux-trapping, but the mechanism may change to low misorientation angles defects, less than ~6 ∘ , when the intergranular magnetic field is approximately parallel to the c -axis (~60 Oe).
ISSN:0957-4522
1573-482X
DOI:10.1007/s10854-017-7403-7