Meissner transport current in flat films of arbitrary shape and a magnetic trap for cold atoms

Vladimir Sokolovsky; Leonid Prigozhin; Valery Dikovsky

doi:10.1088/0953-2048/23/6/065003

Meissner transport current in flat films of arbitrary shape and a magnetic trap for cold atoms

Vladimir Sokolovsky, Leonid Prigozhin, Valery Dikovsky

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

17 Scopus citations

Abstract

The use of superconducting films in the Meissner state reduces the level of noise in micro-and nanochips. Here we present a numerical scheme for computing the Meissner transport current distribution in superconducting films of arbitrary shape, including multiply connected films. The scheme is used for simulating a 3D magnetic trap for cold atoms. Our algorithm is easily generalized for computing the Meissner-London distribution of transport current.

Original language	English
Article number	065003
Journal	Superconductor Science and Technology
Volume	23
Issue number	6
DOIs	https://doi.org/10.1088/0953-2048/23/6/065003
State	Published - 3 May 2010

ASJC Scopus subject areas

Ceramics and Composites
Condensed Matter Physics
Metals and Alloys
Electrical and Electronic Engineering
Materials Chemistry

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10.1088/0953-2048/23/6/065003

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abstract = "The use of superconducting films in the Meissner state reduces the level of noise in micro-and nanochips. Here we present a numerical scheme for computing the Meissner transport current distribution in superconducting films of arbitrary shape, including multiply connected films. The scheme is used for simulating a 3D magnetic trap for cold atoms. Our algorithm is easily generalized for computing the Meissner-London distribution of transport current.",

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AB - The use of superconducting films in the Meissner state reduces the level of noise in micro-and nanochips. Here we present a numerical scheme for computing the Meissner transport current distribution in superconducting films of arbitrary shape, including multiply connected films. The scheme is used for simulating a 3D magnetic trap for cold atoms. Our algorithm is easily generalized for computing the Meissner-London distribution of transport current.

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Meissner transport current in flat films of arbitrary shape and a magnetic trap for cold atoms

Abstract

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