Publikation: On ultrafast magnetic flux dendrite propagation into thin superconducting films
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2005
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Physical Review B. 2005, 72, 024532. Available under: doi: 10.1103/PhysRevB.72.024532
Zusammenfassung
We suggest a theoretical model allowing to find analytically the velocity of a magnetic flux dendrite penetration into thin superconducting films. The key assumptions for this model are based upon experimental observations. We treat a dendrite tip motion as a propagating flux jump instability. Two different regimes of dendrite propagation are found: A fast initial stage is followed by a slow stage, which sets in as soon as a dendrite enters into the vortex-free region. The theoretical results and experimental data obtained by a magneto-optic pump-probe technique are compared and a good agreement between the calculations and measurements is found.
Zusammenfassung in einer weiteren Sprache
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530 Physik
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flux dendrite, flux jumps, flux penetration
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BIEHLER, Björn, Bernd-Uwe RUNGE, Paul LEIDERER, Roman G. MINTS, 2005. On ultrafast magnetic flux dendrite propagation into thin superconducting films. In: Physical Review B. 2005, 72, 024532. Available under: doi: 10.1103/PhysRevB.72.024532BibTex
@article{Biehler2005ultra-8945,
year={2005},
doi={10.1103/PhysRevB.72.024532},
title={On ultrafast magnetic flux dendrite propagation into thin superconducting films},
volume={72},
journal={Physical Review B},
author={Biehler, Björn and Runge, Bernd-Uwe and Leiderer, Paul and Mints, Roman G.},
note={Article Number: 024532}
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<dcterms:abstract xml:lang="eng">We suggest a theoretical model allowing to find analytically the velocity of a magnetic flux dendrite penetration into thin superconducting films. The key assumptions for this model are based upon experimental observations. We treat a dendrite tip motion as a propagating flux jump instability. Two different regimes of dendrite propagation are found: A fast initial stage is followed by a slow stage, which sets in as soon as a dendrite enters into the vortex-free region. The theoretical results and experimental data obtained by a magneto-optic pump-probe technique are compared and a good agreement between the calculations and measurements is found.</dcterms:abstract>
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