Interplay of dendritic avalanches and gradual flux penetration in superconducting MgB2 films

D. V. Shantsev; P. E. Goa; F. L. Barkov; T. H. Johansen; W. N. Kang; S. I. Lee

doi:10.1088/0953-2048/16/5/304

Interplay of dendritic avalanches and gradual flux penetration in superconducting MgB₂ films

D. V. Shantsev, P. E. Goa, F. L. Barkov, T. H. Johansen, W. N. Kang, S. I. Lee

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Magneto-optical imaging was used to study a zero-field-cooled MgB₂ film at 9.6 K where in a slowly increasing field the flux penetrates by an abrupt formation of large dendritic structures. Simultaneously, a gradual flux penetration takes place, eventually covering the dendrites, and a detailed analysis of this process is reported. We find an anomalously high gradient of the flux density across a dendrite branch, and a peak value that decreases as the applied field increases. This unexpected behaviour is reproduced by flux creep simulations based on the non-local field-current relation in the perpendicular geometry. The simulations also provide indirect evidence that flux dendrites are formed at an elevated local temperature, consistent with a thermo-magnetic mechanism of the instability.

Original language	English
Pages (from-to)	566-570
Number of pages	5
Journal	Superconductor Science and Technology
Volume	16
Issue number	5
DOIs	https://doi.org/10.1088/0953-2048/16/5/304
State	Published - May 2003
Externally published	Yes

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title = "Interplay of dendritic avalanches and gradual flux penetration in superconducting MgB2 films",

abstract = "Magneto-optical imaging was used to study a zero-field-cooled MgB2 film at 9.6 K where in a slowly increasing field the flux penetrates by an abrupt formation of large dendritic structures. Simultaneously, a gradual flux penetration takes place, eventually covering the dendrites, and a detailed analysis of this process is reported. We find an anomalously high gradient of the flux density across a dendrite branch, and a peak value that decreases as the applied field increases. This unexpected behaviour is reproduced by flux creep simulations based on the non-local field-current relation in the perpendicular geometry. The simulations also provide indirect evidence that flux dendrites are formed at an elevated local temperature, consistent with a thermo-magnetic mechanism of the instability.",

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T1 - Interplay of dendritic avalanches and gradual flux penetration in superconducting MgB2 films

AU - Shantsev, D. V.

AU - Goa, P. E.

AU - Barkov, F. L.

AU - Johansen, T. H.

AU - Kang, W. N.

AU - Lee, S. I.

PY - 2003/5

Y1 - 2003/5

N2 - Magneto-optical imaging was used to study a zero-field-cooled MgB2 film at 9.6 K where in a slowly increasing field the flux penetrates by an abrupt formation of large dendritic structures. Simultaneously, a gradual flux penetration takes place, eventually covering the dendrites, and a detailed analysis of this process is reported. We find an anomalously high gradient of the flux density across a dendrite branch, and a peak value that decreases as the applied field increases. This unexpected behaviour is reproduced by flux creep simulations based on the non-local field-current relation in the perpendicular geometry. The simulations also provide indirect evidence that flux dendrites are formed at an elevated local temperature, consistent with a thermo-magnetic mechanism of the instability.

AB - Magneto-optical imaging was used to study a zero-field-cooled MgB2 film at 9.6 K where in a slowly increasing field the flux penetrates by an abrupt formation of large dendritic structures. Simultaneously, a gradual flux penetration takes place, eventually covering the dendrites, and a detailed analysis of this process is reported. We find an anomalously high gradient of the flux density across a dendrite branch, and a peak value that decreases as the applied field increases. This unexpected behaviour is reproduced by flux creep simulations based on the non-local field-current relation in the perpendicular geometry. The simulations also provide indirect evidence that flux dendrites are formed at an elevated local temperature, consistent with a thermo-magnetic mechanism of the instability.

UR - https://www.scopus.com/pages/publications/0038188737

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DO - 10.1088/0953-2048/16/5/304

M3 - Article

AN - SCOPUS:0038188737

SN - 0953-2048

VL - 16

SP - 566

EP - 570

JO - Superconductor Science and Technology

JF - Superconductor Science and Technology

IS - 5

ER -

Interplay of dendritic avalanches and gradual flux penetration in superconducting MgB₂ films

Abstract

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