Influence of microscopic defects in type-II superconducting thin films on the magnetic flux penetration

Eisenmenger, Johannes; Leiderer, Paul; Wallenhorst, M.; Dötsch, H.

doi:10.1103/physrevb.64.104503

Cited by 17 publications

(16 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…One should note that the deformed magnetic field profiles are the combined effects of vortex current around antidots and external current crowding at antidots. The similar phenomena were also observed at topological defects due to the Meissner current or external current [62][63][64][65][66]. By comparing the evolutions of magnetic field of S A and S B , one can see that the equivalence of the unit cells of the observed ice-like states are broken by the external current (symmetry break) although the different vortexoccupations in unit cells contribute the same free energy to the vortex system in the case of no applied current.…”

Section: Stability Of Degenerate Vortex States and Confinement Effectsupporting

confidence: 64%

Stability of degenerate vortex states and multi-quanta confinement effects in a nanostructured superconductor with Kagome lattice of elongated antidots

Xue

et al. 2018

New J. Phys.

View full text Add to dashboard Cite

In the present work, we directly visualize the multi-quanta cages (MQCs) consisting of the giant vortices pinned by the elongated antidots using low-temperature scanning Hall probe microscopy. The periodic but sufficiently isolated MQCs, observed at various magnetic fields, are in a good agreement with the simulated vortex states based on the time-dependent Ginzburg-Landau (tdGL) equations. Due to the competition between the interstitial vortices and the pinned giant vortices, the formation and collapse of the MQCs can be tuned by varying magnetic field. The experimental statistics of the interstitial vortices confined in the MQCs show that the interstitial vortex patterns become more disordered at higher magnetic fields. The stability of the degenerate vortex states and the multi-quanta confinement effects under an external current are also investigated by using the tdGL simulations. The splitting of the free energy of the degenerate vortex states indicates that applying external current can eliminate parts of the degenerate vortex states.

show abstract

Section: Stability Of Degenerate Vortex States and Confinement Effectsupporting

confidence: 64%

Stability of degenerate vortex states and multi-quanta confinement effects in a nanostructured superconductor with Kagome lattice of elongated antidots

Xue

et al. 2018

New J. Phys.

View full text Add to dashboard Cite

show abstract

“…These are related to the singularities in magnetic induction found at the edges of current-carrying 2D conductors, and were observed in the magneto-optical experiments of Ref. 12. In our case one would not expect to resolve this fine structure experimentally due to the small actual hole size combined with the relatively large distance between sample and Hall probe.…”

Section: Discussion and Model Of Flux Channelingmentioning

confidence: 55%

“…This indicates a strong interaction between supercurrents circulating the holes and those due to bulk induction gradients, similar to that revealed in magneto-optical images of flux penetration in a YBCO film with several larger ͑40-m͒ circular holes. 12 While we believe that the vortices flow out of the sample upon field removal, we cannot rule out the possibility that antivortices are channeling in the opposite direction, and the process is one of systematic vortex-antivortex annihilation. The latter would be the expected mechanism of magnetization reversal in homogeneous thin films.…”

Section: Methodsmentioning

confidence: 84%

Anisotropic vortex channeling inYBa2Cu3O7–δthin films with

et al. 2005

View full text Add to dashboard Cite

Scanning Hall probe microscopy has been used to make a microscopic study of flux structures and dynamics in yttrium barium copper oxide thin-film disks containing a regular 10-m-period square array of 2.5-m-sized holes ͑antidots͒. Images obtained after field cooling the sample to 77 K in very low fields reveal that the holes can trap two flux quanta at this temperature. Scans obtained after zero-field cooling ͑ZFC͒ to 77 K and a subsequent applied field cycle clearly display preferential flux channeling along chains of antidots in the direction of maximum induction gradient. Remarkably, upon reversal of field sweep direction, we observe flux "streaming" out of the holes towards the sample edges with almost uniform density flux "stripes" bridging the holes in the exit direction. We estimate that the antidots can preferentially trap about 15 flux quanta in these ZFC experiments. Classical electrodynamics simulations of our samples appear to be in good qualitative agreement with our results, indicating that many of the observed phenomena may be geometrical effects that depend primarily on the shape and topology of the sample, and potential applications are discussed.

show abstract

“…The motion of magnetic flux in type-II superconducting films can to a large extent be controlled by introduction of artificial micro-and nanostructures, such as antidots (holes), [1][2][3] magnetic dots, 4,5 thickness modulations, 6,7 grain boundaries, 8,9 slits, 10 or magnetic domain walls in superconductor/ferromagnet hybrids. 11,12 Such structures are key building blocks for successful realization of fluxonics devices like vortex ratchets, pumps and lenses, etc.…”

Section: Introductionmentioning

confidence: 99%

Mechanism for flux guidance by micrometric antidot arrays in superconducting films

et al. 2012

View full text Add to dashboard Cite

Abstract"A study of magnetic flux penetration in a superconducting film patterned with arrays of micron-sized antidots (microholes) is reported. Magneto-optical imaging (MOI) of a YBa(2)Cu(3)O(x) film shaped as a long strip with perpendicular antidot arrays revealed both strong guidance of flux and, at the same time, large perturbations of the overall flux penetration and flow of current. These results are compared with a numerical flux creep simulation of a thin superconductor with the same antidot pattern. To perform calculations on such a complex geometry, an efficient numerical scheme for handling the boundary conditions of the antidots and the nonlocal electrodynamics was developed. The simulations reproduce essentially all features of the MOI results. In addition, the numerical results give insight into all other key quantities (e. g., the electrical field), which become extremely large in the narrow channels connecting the antidots." A study of magnetic flux penetration in a superconducting film patterned with arrays of micron-sized antidots (microholes) is reported. Magneto-optical imaging (MOI) of a YBa 2 Cu 3 O x film shaped as a long strip with perpendicular antidot arrays revealed both strong guidance of flux and, at the same time, large perturbations of the overall flux penetration and flow of current. These results are compared with a numerical flux creep simulation of a thin superconductor with the same antidot pattern. To perform calculations on such a complex geometry, an efficient numerical scheme for handling the boundary conditions of the antidots and the nonlocal electrodynamics was developed. The simulations reproduce essentially all features of the MOI results. In addition, the numerical results give insight into all other key quantities (e.g., the electrical field), which become extremely large in the narrow channels connecting the antidots.

show abstract

Influence of microscopic defects in type-II superconducting thin films on the magnetic flux penetration

Cited by 17 publications

References 43 publications

Stability of degenerate vortex states and multi-quanta confinement effects in a nanostructured superconductor with Kagome lattice of elongated antidots

Stability of degenerate vortex states and multi-quanta confinement effects in a nanostructured superconductor with Kagome lattice of elongated antidots

Anisotropic vortex channeling inYBa2Cu3O7–δthin films with

Mechanism for flux guidance by micrometric antidot arrays in superconducting films

Contact Info

Product

Resources

About