Dirk Grundler
Dirk Grundler
EPF Lausanne, STI-IMX-LMGN, Switzerland
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Zitiert von
Zitiert von
VV Kruglyak, SO Demokritov, D Grundler
Journal of Physics D: Applied Physics 43 (26), 264001, 2010
Large Rashba splitting in InAs quantum wells due to electron wave function penetration into the barrier layers
D Grundler
Physical review letters 84 (26), 6074, 2000
Review and prospects of magnonic crystals and devices with reprogrammable band structure
M Krawczyk, D Grundler
Journal of Physics: Condensed Matter 26 (12), 123202, 2014
Magnonics: Spin waves on the nanoscale
S Neusser, D Grundler
Advanced Materials 21 (28), 2927-2932, 2009
The 2021 Magnonics Roadmap
A Barman, et al.
J. Phys.: Condens. Matter,, 2021
Advances in Magnetics Roadmap on Spin-Wave Computing
AV Chumak, P Kabos, M Wu, C Abert, C Adelmann, AO Adeyeye, ...
IEEE Transactions on Magnetics 58 (6), 1-72, 2022
Universal helimagnon and skyrmion excitations in metallic, semiconducting and insulating chiral magnets
T Schwarze, J Waizner, M Garst, A Bauer, I Stasinopoulos, H Berger, ...
Nature materials 14 (5), 478-483, 2015
Magnetic thin-film insulator with ultra-low spin wave damping for coherent nanomagnonics
H Yu, OA Kelly, V Cros, R Bernard, P Bortolotti, A Anane, F Brandl, ...
Scientific reports 4, 6848, 2014
Making a reconfigurable artificial crystal by ordering bistable magnetic nanowires
J Topp, D Heitmann, MP Kostylev, D Grundler
Physical review letters 104 (20), 207205, 2010
Collective spin excitations of helices and magnetic skyrmions: review and perspectives of magnonics in non-centrosymmetric magnets
M Garst, J Waizner, D Grundler
Journal of Physics D: Applied Physics 50 (29), 293002, 2017
Omnidirectional spin-wave nanograting coupler
H Yu, G Duerr, R Huber, M Bahr, T Schwarze, F Brandl, D Grundler
Nature communications 4, 2702, 2013
Approaching soft X-ray wavelengths in nanomagnet-based microwave technology
H Yu, O d’ Allivy Kelly, V Cros, R Bernard, P Bortolotti, A Anane, F Brandl, ...
Nature Communications 7, 11255, 2016
Ballistic spin transport and spin interference in ferromagnet/InAs (2DES)/ferromagnet devices
T Matsuyama, CM Hu, D Grundler, G Meier, U Merkt
Physical Review B 65 (15), 155322, 2002
Anisotropic propagation and damping of spin waves in a nanopatterned antidot lattice
S Neusser, G Duerr, HG Bauer, S Tacchi, M Madami, G Woltersdorf, ...
Physical review letters 105 (6), 067208, 2010
Spin-wave interference in microscopic rings
J Podbielski, F Giesen, D Grundler
Physical review letters 96 (16), 167207, 2006
Localization, confinement, and field-controlled propagation of spin waves in Ni_ {80} Fe_ {20} antidot lattices
S Neusser, B Botters, D Grundler
Physical Review B 78 (5), 054406, 2008
Forbidden Band Gaps in the Spin-Wave Spectrum of a Two-Dimensional Bicomponent Magnonic Crystal
S Tacchi, G Duerr, JW Klos, M Madami, S Neusser, G Gubbiotti, G Carlotti, ...
Physical Review Letters 109 (13), 137202, 2012
Reconfigurable magnonics heats up
D Grundler
Nature Physics 11 (6), 438-441, 2015
In situ manipulation of magnetic anisotropy in magnetite thin films
A Brandlmaier, S Geprägs, M Weiler, A Boger, M Opel, H Huebl, C Bihler, ...
Physical Review B 77 (10), 104445, 2008
Nonreciprocal surface acoustic wave propagation via magneto-rotation coupling
M Xu, K Yamamoto, J Puebla, K Baumgaertl, B Rana, K Miura, ...
Sci. Adv. 6 (32), eabb1724, 2020
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