APS March Meeting 2017
Volume 62, Number 4
Monday–Friday, March 13–17, 2017;
New Orleans, Louisiana
Session K50: Nanomagnets
8:00 AM–11:00 AM,
Wednesday, March 15, 2017
Room: 397
Sponsoring
Units:
GMAG DMP
Chair: Julie Karel, Monash University
Abstract ID: BAPS.2017.MAR.K50.7
Abstract: K50.00007 : Wavevector dependent damping in nanomagnets
9:12 AM–9:48 AM
Preview Abstract
Abstract
Author:
Hans Nembach
(NIST and JILA, University of Colorado)
Nanomagnets are the building blocks of spintronics devices. This makes it
important to understand the magnetization dynamics in nanomagnets from an
application oriented view. From a more basic research orientated
perspective, nanomagnets provide the opportunity to determine, if the
localization of spin-wave modes influences their dynamics. We measured
localized spin-wave modes in individual Ni$_{\mathrm{80}}$Fe$_{\mathrm{20}}$
nanomagnets ranging from 80 nm to 400 nm in size by heterodyne
magneto-optical microwave microscopy. We compared our measured spectra with
micromagnetic simulations and were able to identify two spin-wave modes, the
center-mode and the end-mode. We determined that the Gilbert damping for
these localized spinwave modes depends on the size of the nanomagnet and on
the respective spin-wave mode. We were able to exclude that the observed
damping originates from an area of enhanced damping at the edge of the
nanomagnets. A detailed analysis showed that the results can be understood
within the model of Bar'yakhtar for damping in ferromagnets, where exchange
contributions to the relaxation are considered. These additional
contributions depend on the curvature of the dynamic magnetization or, in
Fourier space, on k$^{\mathrm{2}}$, where k is the wavevector of the
respective Fourier components of the spatial non-uniformities. We also
studied the k$^{\mathrm{2}}$-damping for perpendicular standing spin-wave
modes (PSSWs) in Ni$_{\mathrm{80}}$Fe$_{\mathrm{20}}$ films with a
thicknesses starting at 75 nm. Our results showed that any
k$^{\mathrm{2}}$-damping contributions must be significantly smaller than
what we have found in the nanomagnets. In order to determine if this
k$^{\mathrm{2}}$-damping originates from the interface, we compared the
damping in nanomagnets for 3 nm, 10 nm and 15 nm thick
Ni$_{\mathrm{80}}$Fe$_{\mathrm{20}}$ layers. We found, that the
k$^{\mathrm{2}}$-damping for the nanomagnets decreases with increasing
thickness of the ferromagnetic layer. This indicates that the
k$^{\mathrm{2}}$-damping in the studied system has a strong interfacial
contribution, which explains, why we were not able to measure any k2-damping
for the PSSWs.
1) V. G. Bar'yakhtar et al., Zh. Eksp. Teor. Fiz. 91, 1454 (1986)
2) H.T. Nembach et al., Phys. Rev. Lett., 11, 117201 (2013)
3) M. Schoen et al., Phys. Rev. B, 91, 184417 (2015)
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.MAR.K50.7