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Evidence for quantum tunneling of vortices in superconductors

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Abstract

Flux creep in disordered superconductors may be governed by quantum tunneling of Abrikosov vortices rather than by thermal activation processes. The expectation is that in the quantum tunneling regime the creep rate would be temperature independent. This assumes that the parameters describing the pinning potential and other aspects of the superconducting films are temperature independent. In the case of extremely thin superconducting films the coherence length retains its temperature dependence well into the quantum tunneling regime, leading to an unusual temperature dependence of the electrical resistance in this regime. This has been observed in ultrathin superconducting films of Pb, Al, and Bi. In low magnetic fields, at low temperatures, sheet resistances vary with temperature as R≈R0 exp(T/T0), where T0 and R0 are constants.

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Author notes

  1. Y. Liu

    Present address: the University of Colorado, USA

  2. D. B. Haviland

    Present address: Chalmers Technology University, USA

Authors and Affiliations

  1. School of Physics and Astronomy, University of Minnesota, 55455, Minneapolis, MN, USA

    Y. Liu, D. B. Haviland, L. I. Glazman & A. M. Goldman

  2. the Theoretical Physics Institute, University of Minnesota, USA

    L. I. Glazman

Authors
  1. Y. Liu
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  2. D. B. Haviland
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  3. L. I. Glazman
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  4. A. M. Goldman
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Liu, Y., Haviland, D.B., Glazman, L.I. et al. Evidence for quantum tunneling of vortices in superconductors. J Low Temp Phys 89, 187–196 (1992). https://doi.org/10.1007/BF00692591

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