APS March Meeting 2015
Volume 60, Number 1
Monday–Friday, March 2–6, 2015;
San Antonio, Texas
Session G53: Invited Session: Microscopic Understanding of Dynamics of Localized Spin Wave Modes
11:15 AM–2:15 PM,
Tuesday, March 3, 2015
Room: Grand Ballroom C3
Sponsoring
Units:
GMAG DCMP
Abstract ID: BAPS.2015.MAR.G53.3
Abstract: G53.00003 : Mode- and Size-Dependent Landau-Lifshitz Damping in Magnetic Nanostructures
12:27 PM–1:03 PM
Preview Abstract
Abstract
Author:
Thomas Silva
(NIST - Boulder)
At nanometer dimensions, magnetic excitation bands transform into discrete
eigenmodes with nontrivial shape and size dependence. The eigenmode spectral
peak positions are well-understood in terms of conventional micromagnetics
[R. D. McMichael and M. D. Stiles, J. Appl. Phys. 97, 10J901 (2005)][H. T.
Nembach, et al., Phys. Rev. B 83, 094427 (2011)]. However, the effect of
finite size on the damping process is not yet settled. Conventional
micromagnetics does not predict any effect, insofar as numerical
formulations of magnetization dynamics are usually predicated on the
assumption of local damping. However, nonlocal damping has been predicted
for metals via nontrivial scattering between coherent excitations and
uncorrelated spin-flip electron-hole pairs [Y. Tserkovnyak, et al., Phys.
Rev. B 79, 094415 (2009)] [I. V. Baryakhtar and V. Baryakhtar, Ukr. Phys.
Journ. 43, 1433 (1998)]. In particular, theory predicts a dependence of
damping on the eigenmode curvature. We developed a novel Kerr microscope to
measure ferromagnetic resonance in deep-sub-wavelength structures. We use
heterodyne mixing for phase-sensitive detection of the magnetization
dynamics with a signal-to-noise ratio proportional to the square-root of the
scattered optical power. The heterodyne magneto-optic microwave microscope
(H-MOMM) is optimized for cw measurements to extract the damping parameter.
We measured damping in e-beam-patterned 10-nm-thick Permalloy nanomagnets
ranging in size from 100 to 400 nm. We observe two eigenmodes; the end-mode,
with an exponentially decaying amplitude for increasing distance from the
ends along the applied field direction, and the center mode, with relatively
uniform amplitude throughout much of the nanomagnet volume, though with two
nodes near the ends. The center-mode damping increases with decreasing
nanomagnet size, but the end-mode damping exhibits the opposite trend [H. T.
Nembach, et al., Phys. Rev. Lett. 110, 117201 (2013)]. We quantitatively fit
the data with the Barakhtar/Tserkovnyak theory, but obtain a much larger
dependence on sample size than expected from microscopic considerations.
Subsequent measurements by us of perpendicular standing spin waves in thick
Permalloy films, as well as additional H-MOMM investigations of variable
thickness Permalloy nanomagnets, strongly suggest that the observed
non-local damping is enhanced with decreasing film thickness. Such thickness
dependence is not theoretically predicted, and indicates that
surface/interface scattering is important.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.MAR.G53.3