The role of a layered structure in superconducting pinning properties is still at a debate. The effects of the vortex shape, which can assume for example a staircase form, could influence the interplay with extrinsic pinning coming from the specific defects of the material, thus inducing an effective magnetic field dependence. To enlighten this role, we analysed the angular dependence of flux pinning energy (,) as a function of magnetic field in FeSeTe thin film by considering the field components along the -plane of the crystal structure and the -axis direction. (,) has been evaluated from magneto-resistivity measurements acquired at different orientations between the applied field up to 16 T and FeSeTe thin films grown on a CaF substrate. We observed that the (,) shows an anisotropic trend as a function of both the intensity and the direction of the applied field. Such a behaviour can be correlated to the presence of extended defects elongated in the -planes, thus mimicking a layered superconductor, as we observed in the microstructure of the compound. The comparison of FeSeTe with other superconducting materials provides a more general understanding on the flux pinning energy in layered superconductors.
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| http://dx.doi.org/10.3390/ma14185289 | DOI Listing |
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