Abstract
Superconductors are well known for their ability to screen out magnetic fields. In type-II superconductors, as the magnetic field pressure is progressively increased, magnetic flux accumulates at the periphery of the sample, very much like charges accumulate in a capacitor when voltage is increased. As for capacitors, exceeding certain threshold field causes the blocked magnetic flux to abruptly penetrate into the sample. This phenomenon, triggered by a thermomagnetic instability, is somewhat analogous to the dielectric breakdown of the capacitor and leaves behind a similar Lichtenberg imprinting. Even though electrical breakdown threshold has been extensively studied in dielectrics, little information is known about the statistical distribution of the thermomagnetic breakdown in superconductors. In this work, we address this problem by performing magneto-optical imaging experiments on a Nb film where nanometric heating elements are used to rapidly erase the magnetic history of the sample. We demonstrate that the size and shape distributions of avalanches permits to unambiguously identify the transition between two regimes where either thermal diffusivity or magnetic diffusivity dominates. Clear criteria for discriminating athermal dynamic avalanches from thermally driven avalanches are introduced. This allows us to provide the first precise determination of the threshold field of the thermomagnetic breakdown and unveil the details of the transition from finger-like magnetic burst to dendritic branching morphology. These findings open a new avenue in the interdisciplinary exploration of catastrophic avalanches through non destructive repeatable experiments.
Highlights
Superconductors are well known for their ability to screen out magnetic fields
This analysis has far reaching pluridisciplinary implications touching a large diversity of phenomena, such as dielectric breakdown where σ corresponds to the bias voltage[1], electromigration with σ being associated with the current density stimulating atom diffusion[2], avalanches where σ represents the angle of the slope[3], or even popcorn explosion with σ being the temperature of the hot plate[4]
Superconducting materials offer an ideal playground to investigate the probability density function (PDF) of the threshold stress σth in the very same sample, ruling out completely the spreading factors associated to unavoidable variations in the replicas of the system
Summary
Received: 11 November 2018 Accepted: 22 January 2019 Published online: 06 March 2019. Clear criteria for discriminating athermal dynamic avalanches from thermally driven avalanches are introduced This allows us to provide the first precise determination of the threshold field of the thermomagnetic breakdown and unveil the details of the transition from finger-like magnetic burst to dendritic branching morphology. Even though the MO imaging technique is insensitive to the local temperature and does not provide information on the time evolution of the events, the obtained PDF unravels a regime of small avalanches characteristic of a rapid evacuation of heat, separated from a regime of larger avalanches resulting from a substantial magnetic diffusivity and reduced heat spreading This precious finding allows in turn for a precise determination of the threshold magnetic field Hth and its distribution probability with unprecedented resolution. Repeating the statistical analysis at several temperatures, we highlight the presence of two distinct Hth distributions corresponding to small and large avalanches, peaking respectively at low and high magnetic fields and coexisting at intermediate temperatures
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
