Biologically encoded magnonics

The capability to engineer magnon states in confined geometries is vital to future nano-magnonics. Here the authors demonstrate that the topology of the magnon bands is determined by the local arrangement and orientation of nanoparticles and can be controlled by the genotype of magnetotactic bacteri...

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Autores principales: Benjamin W. Zingsem, Thomas Feggeler, Alexandra Terwey, Sara Ghaisari, Detlef Spoddig, Damien Faivre, Ralf Meckenstock, Michael Farle, Michael Winklhofer
Formato: article
Lenguaje:EN
Publicado: Nature Portfolio 2019
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Acceso en línea:https://doaj.org/article/8a6c93516a104f7d9769191fa32a4306
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spelling oai:doaj.org-article:8a6c93516a104f7d9769191fa32a43062021-12-02T14:38:47ZBiologically encoded magnonics10.1038/s41467-019-12219-02041-1723https://doaj.org/article/8a6c93516a104f7d9769191fa32a43062019-09-01T00:00:00Zhttps://doi.org/10.1038/s41467-019-12219-0https://doaj.org/toc/2041-1723The capability to engineer magnon states in confined geometries is vital to future nano-magnonics. Here the authors demonstrate that the topology of the magnon bands is determined by the local arrangement and orientation of nanoparticles and can be controlled by the genotype of magnetotactic bacteria.Benjamin W. ZingsemThomas FeggelerAlexandra TerweySara GhaisariDetlef SpoddigDamien FaivreRalf MeckenstockMichael FarleMichael WinklhoferNature PortfolioarticleScienceQENNature Communications, Vol 10, Iss 1, Pp 1-8 (2019)
institution DOAJ
collection DOAJ
language EN
topic Science
Q
spellingShingle Science
Q
Benjamin W. Zingsem
Thomas Feggeler
Alexandra Terwey
Sara Ghaisari
Detlef Spoddig
Damien Faivre
Ralf Meckenstock
Michael Farle
Michael Winklhofer
Biologically encoded magnonics
description The capability to engineer magnon states in confined geometries is vital to future nano-magnonics. Here the authors demonstrate that the topology of the magnon bands is determined by the local arrangement and orientation of nanoparticles and can be controlled by the genotype of magnetotactic bacteria.
format article
author Benjamin W. Zingsem
Thomas Feggeler
Alexandra Terwey
Sara Ghaisari
Detlef Spoddig
Damien Faivre
Ralf Meckenstock
Michael Farle
Michael Winklhofer
author_facet Benjamin W. Zingsem
Thomas Feggeler
Alexandra Terwey
Sara Ghaisari
Detlef Spoddig
Damien Faivre
Ralf Meckenstock
Michael Farle
Michael Winklhofer
author_sort Benjamin W. Zingsem
title Biologically encoded magnonics
title_short Biologically encoded magnonics
title_full Biologically encoded magnonics
title_fullStr Biologically encoded magnonics
title_full_unstemmed Biologically encoded magnonics
title_sort biologically encoded magnonics
publisher Nature Portfolio
publishDate 2019
url https://doaj.org/article/8a6c93516a104f7d9769191fa32a4306
work_keys_str_mv AT benjaminwzingsem biologicallyencodedmagnonics
AT thomasfeggeler biologicallyencodedmagnonics
AT alexandraterwey biologicallyencodedmagnonics
AT saraghaisari biologicallyencodedmagnonics
AT detlefspoddig biologicallyencodedmagnonics
AT damienfaivre biologicallyencodedmagnonics
AT ralfmeckenstock biologicallyencodedmagnonics
AT michaelfarle biologicallyencodedmagnonics
AT michaelwinklhofer biologicallyencodedmagnonics
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