APS March Meeting 2017
Volume 62, Number 4
Monday–Friday, March 13–17, 2017;
New Orleans, Louisiana
Session R47: Spin-Orbit Torque III and Chiral Domain Walls
8:00 AM–11:00 AM,
Thursday, March 16, 2017
Room: 394
Sponsoring
Units:
GMAG DMP FIAP
Chair: Igor Barsukov, University of California, Riverside
Abstract ID: BAPS.2017.MAR.R47.4
Abstract: R47.00004 : Current-induced spin torques in inversion broken materials
8:36 AM–9:12 AM
Preview Abstract
Abstract
Author:
Hidekazu Kurebayashi
(University College London)
The spin-orbit interaction has been providing richness and greatness of
magnetism and spintronics. In solid states, it couples electron's momentum
and spins, which make it possible to electrically excite or detect spin
accumulation/currents. Looking at localized spins, it helps magnetic
anisotropies emerge (together with the magnetic-dipole interaction) where
the sample's real space symmetry, such as surface-induced two-fold and
crystalline-induced four-fold, is reflected on the magnetic energy
landscape. Along this line, we can also think of what will happen when we
lower the sample symmetry to ``inversion broken''. In this case, an electron
propagating along one direction is, on the symmetry argument, no longer
required to be on the same state as ones moving to the opposite direction.
The spin-orbit interaction picks up this and causes a preferential spin
direction for each electronic state, as a whole, forming spin textures in
momentum space.
These spin textures are a fascinating playground for developing spin-charge
conversion effects. Although the electric excitation of spin textured
materials has been known as the Edelstein effect [1] for more than two
decades, its real spintronic use, e.g. magnetisation control [2], has been a
much more recent interest. By employing microwave techniques to electrically
exert magnetic torques through spin textures, we have successfully excite
ferromagnetic resonance using this mechanism and characterise spin-orbit
properties in our samples [3].
In this talk, I will summarise our recent results on spin torque effects
using spin textures in inversion-broken materials. I will show microscopic
origins of current-induced magnetisation control by the Edelstein effects in
single ferromagnetic layers [3,4], as well as similar experiments by using
non-magnetic inversion-broken layers [5] where we observed two spin torques,
one arising from the spin-texture effect that co-exist with the other one
from the spin-Hall effect. As the final part, I will present our latest
results from our research.
[1] Edelstein, Solid State. Comm. 73 233 (1990).
[2] Chernyshov, et al., Nature Phys., 5 656 (2009).
[3] Fang et al., Nature Nanotech. 9 211 (2011).
[4] Kurebayashi, et al., Nature Nanotech, 9 211 (2014).
[5] Skinner et al., Nature Comm. 6 6730 (2015).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.MAR.R47.4