Remotely induced magnetism in a normal metal using a superconducting spin-valve
A switchable induced magnetic moment in a non-magnetic metal that is separated from a ferromagnet by a thick superconducting layer contradicts existing models. Superconducting spintronics has emerged in the past decade as a promising new field that seeks to open a new dimension for nanoelectronics b...
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Veröffentlicht in: | Nature physics 2016-01, Vol.12 (1), p.57-61 |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | A switchable induced magnetic moment in a non-magnetic metal that is separated from a ferromagnet by a thick superconducting layer contradicts existing models.
Superconducting spintronics has emerged in the past decade as a promising new field that seeks to open a new dimension for nanoelectronics by utilizing the internal spin structure of the superconducting Cooper pair as a new degree of freedom
1
,
2
. Its basic building blocks are spin-triplet Cooper pairs with equally aligned spins, which are promoted by proximity of a conventional superconductor to a ferromagnetic material with inhomogeneous macroscopic magnetization
3
. Using low-energy muon spin-rotation experiments we find an unanticipated effect, in contradiction with the existing theoretical models of superconductivity and ferromagnetism: the appearance of a magnetization in a thin layer of a non-magnetic metal (gold), separated from a ferromagnetic double layer by a 50-nm-thick superconducting layer of Nb. The effect can be controlled either by temperature or by using a magnetic field to control the state of the remote ferromagnetic elements, and may act as a basic building block for a new generation of quantum interference devices based on the spin of a Cooper pair. |
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ISSN: | 1745-2473 1745-2481 |
DOI: | 10.1038/nphys3486 |