Avalanches and self-organized criticality in superconductors

R.J. Wijngaarden; M.S. Welling; C.M. Aegerter; M. Menghini

doi:10.1140/epjb/e2006-00063-7

Avalanches and self-organized criticality in superconductors

R.J. Wijngaarden
, M.S. Welling
, C.M. Aegerter
, M. Menghini

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Abstract

We review the use of superconductors as a playground for the experimental study of front roughening and avalanches. Using the magneto-optical technique, the spatial distribution of the vortex density in the sample is monitored as a function of time. The roughness and growth exponents corresponding to the vortex `landscape' are determined and compared to the exponents that characterize the avalanches in the framework of Self-Organized Criticality. For those situations where a thermo-magnetic instability arises, an analytical non-linear and non-local model is discussed, which is found to be consistent to great detail with the experimental results. On anisotropic substrates, the anisotropy regularizes the avalanches.

Original language	English
Pages (from-to)	117-122
Number of pages	6
Journal	European Physical Journal B. Condensed Matter and Complex Systems
Volume	50
Issue number	1/2
Early online date	20 Feb 2006
DOIs	https://doi.org/10.1140/epjb/e2006-00063-7
Publication status	Published - Mar 2006

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Avalanches and self-organized criticality in superconductors

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