Suppression of flux avalanches in superconducting films by electromagnetic braking

Colauto, F.; Choi, Eun Mi; Lee, J. Y.; Lee, S. I.; Patiño, Edgar J.; Blamire, M. G.; Johansen, T. H.; Ortiz, W.A.

doi:10.1063/1.3350681

Cited by 35 publications

(39 citation statements)

References 28 publications

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“…In this respect, the system is similar to that described in Ref. 16, where dendritic avalanches were suppressed by electromagnetic braking with clear separation between the metal and the superconductor. In that work, the voltage was not measured, but the presence of electromagnetic braking is a clear indication of the existence of a significant voltage induced in the metal by the fast dendritic flux avalanches in the superconductor.…”

supporting

confidence: 56%

“…It is already known that a normal metal layer adjacent to a superconducting film tends to suppress the avalanche activity due to electromagnetic braking, [14][15][16] an effect experienced also in the present work, where we never observed avalanches starting from an edge covered with metal film. However, the Cu layer on the present NbN sample is sufficiently thin to allow branches to partly enter under the Cu electrode.…”

supporting

confidence: 54%

“…While it was shown previously 14,16 that coating a superconductor film with a metal layer strongly suppresses the dendritic instability, we demonstrate here that when flux dendrites actually penetrate into a coated region, they may have a serious impact on the device performance. Therefore, thin superconducting devices experiencing transverse magnetic fields should be carefully designed to be robust against electrical noise of the type reported in this work.…”

mentioning

confidence: 76%

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Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films

Mikheenko¹,

Qviller²,

Vestgården³

et al. 2013

Applied Physics Letters

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Combined voltage and magneto-optical study of magnetic flux flow in superconducting NbN films is reported. The nanosecond-scale voltage pulses appearing during thermomagnetic avalanches have been recorded in films partially coated by a metal layer. Simultaneous magneto-optical imaging and voltage measurements allowed the pulses to be associated with individual flux branches penetrating the superconductor below the metal coating. From detailed characteristics of pulse and flux branches, the electrical field in the superconductor is found to be in the range of 5-50 kV/m, while the propagation speed of the avalanche during its final stage is found to be close to 5 km/s.

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supporting

confidence: 56%

supporting

confidence: 54%

mentioning

confidence: 76%

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Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films

Mikheenko¹,

Qviller²,

Vestgården³

et al. 2013

Applied Physics Letters

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“…This phenomenon arises from the electromagnetic braking of the flux propagation, caused by the eddy currents induced in the conductive layer [5][6][7][8]. The question as to whether a single element of the flux front, i.e., a superconducting vortex, could also undergo any deflection of its trajectory when entering in the region covered by a conducting layer has recently been tackled by appealing to a classical analogy, consisting of a magnetic monopole (the vortex) moving in the vicinity of a metallic film [2].…”

Section: Introductionmentioning

confidence: 99%

Flux penetration in a superconducting film partially capped with a conducting layer

et al. 2017

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The influence of a conducting layer on the magnetic flux penetration in a superconducting Nb film is studied by magneto-optical imaging. The metallic layer partially covering the superconductor provides an additional velocity-dependent damping mechanism for the flux motion that helps to protect the superconducting state when thermomagnetic instabilities develop. If the flux advances with a velocity slower than w = 2/μ 0 σ t, where σ is the cap layer conductivity and t is its thickness, the flux penetration remains unaffected, whereas for incoming flux moving faster than w, the metallic layer becomes an active screening shield. When the metallic layer is replaced by a perfect conductor, it is expected that the flux braking effect will occur for all flux velocities. We investigate this effect by studying Nb samples with a thickness step. Some of the observed features, namely the deflection of the flux trajectories at the border of the thick center, as well as the favored flux penetration at the indentation, are reproduced by time-dependent Ginzburg-Landau simulations.

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“…Alternative means to suppress such flux bursts have been already discussed in the literature, 28,29 the simplest of which we have applied here. By placing a metallic disk (Ag) on top of sample GRAD, one manages to inhibit, via magnetic breaking, 29 the thermomagnetic instabilities that trigger avalanches. The dotted-dashed curve in Figure 2(b) shows the hysteresis loop of sample GRAD with the Ag disk, indicating that flux avalanches are mostly suppressed in this configuration.…”

mentioning

confidence: 99%

Enhanced pinning in superconducting thin films with graded pinning landscapes

Motta

Colauto

Ortiz

et al. 2013

Applied Physics Letters

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A graded distribution of pinning centers (antidots) in superconducting MoGe thin films has been investigated by magnetization and magneto-optical imaging. The pinning landscape has maximum density at the border, decreasing progressively towards the center. At high temperatures and low fields, where this landscape mimics the vortex distribution predicted by the Bean model, an increase of the critical current is observed. At low temperatures and fields, the superconducting performance of the non-uniform sample is also improved due to suppression of thermomagnetic avalanches. These findings emphasize the relevance of non-uniform pinning landscapes, so far experimentally unexplored, on the enhancement of pinning efficiency.

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Suppression of flux avalanches in superconducting films by electromagnetic braking

Cited by 35 publications

References 28 publications

Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films

Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films

Flux penetration in a superconducting film partially capped with a conducting layer

Enhanced pinning in superconducting thin films with graded pinning landscapes

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