TY - JOUR
T1 - Coherent Excitation of Heterosymmetric Spin Waves with Ultrashort Wavelengths
AU - Dieterle, G.
AU - Förster, J.
AU - Stoll, H.
AU - Semisalova, A. S.
AU - Finizio, S.
AU - Gangwar, A.
AU - Weigand, M.
AU - Noske, M.
AU - Fähnle, M.
AU - Bykova, I.
AU - Gräfe, J.
AU - Bozhko, D. A.
AU - Musiienko-Shmarova, H. Yu
AU - Tiberkevich, V.
AU - Slavin, A. N.
AU - Back, C. H.
AU - Raabe, J.
AU - Schütz, G.
AU - Wintz, S.
N1 - Publisher Copyright:
© 2019 American Physical Society.
PY - 2019/3/21
Y1 - 2019/3/21
N2 - In the emerging field of magnonics, spin waves are foreseen as signal carriers for future spintronic information processing and communication devices, owing to both the very low power losses and a high device miniaturization potential predicted for short-wavelength spin waves. Yet, the efficient excitation and controlled propagation of nanoscale spin waves remains a severe challenge. Here, we report the observation of high-amplitude, ultrashort dipole-exchange spin waves (down to 80 nm wavelength at 10 GHz frequency) in a ferromagnetic single layer system, coherently excited by the driven dynamics of a spin vortex core. We used time-resolved x-ray microscopy to directly image such propagating spin waves and their excitation over a wide range of frequencies. By further analysis, we found that these waves exhibit a heterosymmetric mode profile, involving regions with anti-Larmor precession sense and purely linear magnetic oscillation. In particular, this mode profile consists of dynamic vortices with laterally alternating helicity, leading to a partial magnetic flux closure over the film thickness, which is explained by a strong and unexpected mode hybridization. This spin-wave phenomenon observed is a general effect inherent to the dynamics of sufficiently thick ferromagnetic single layer films, independent of the specific excitation method employed.
AB - In the emerging field of magnonics, spin waves are foreseen as signal carriers for future spintronic information processing and communication devices, owing to both the very low power losses and a high device miniaturization potential predicted for short-wavelength spin waves. Yet, the efficient excitation and controlled propagation of nanoscale spin waves remains a severe challenge. Here, we report the observation of high-amplitude, ultrashort dipole-exchange spin waves (down to 80 nm wavelength at 10 GHz frequency) in a ferromagnetic single layer system, coherently excited by the driven dynamics of a spin vortex core. We used time-resolved x-ray microscopy to directly image such propagating spin waves and their excitation over a wide range of frequencies. By further analysis, we found that these waves exhibit a heterosymmetric mode profile, involving regions with anti-Larmor precession sense and purely linear magnetic oscillation. In particular, this mode profile consists of dynamic vortices with laterally alternating helicity, leading to a partial magnetic flux closure over the film thickness, which is explained by a strong and unexpected mode hybridization. This spin-wave phenomenon observed is a general effect inherent to the dynamics of sufficiently thick ferromagnetic single layer films, independent of the specific excitation method employed.
UR - http://www.scopus.com/inward/record.url?scp=85063301724&partnerID=8YFLogxK
U2 - 10.1103/PhysRevLett.122.117202
DO - 10.1103/PhysRevLett.122.117202
M3 - Article
C2 - 30951356
AN - SCOPUS:85063301724
SN - 0031-9007
VL - 122
JO - Physical Review Letters
JF - Physical Review Letters
IS - 11
M1 - 117202
ER -