APS March Meeting 2016
Volume 61, Number 2
Monday–Friday, March 14–18, 2016;
Baltimore, Maryland
Session V19: Magnetic Oxide Thin Films and Heterostructures: Spin Seebeck Effects
2:30 PM–5:30 PM,
Thursday, March 17, 2016
Room: 318
Sponsoring
Units:
GMAG DMP
Chair: Jobu Matsuno, RIKEN
Abstract ID: BAPS.2016.MAR.V19.1
Abstract: V19.00001 : Paramagnetic and Antiferromagnetic Spin Seebeck Effect
2:30 PM–3:06 PM
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Abstract
Author:
Stephen Wu
(Argonne National Laboratory)
We report on the observation of the longitudinal spin Seebeck effect in both
antiferromagnetic and paramagnetic insulators. By using a microscale on-chip
local heater, it is possible to generate a large thermal gradient confined
to the chip surface without a large increase in the total sample
temperature. This technique allows us to easily access low temperatures (200
mK) and high magnetic fields (14 T) through conventional dilution
refrigeration and superconducting magnet setups. By exploring this regime,
we detect the spin Seebeck effect through the spin-flop transition in
antiferromagnetic MnF$_{2}$ when a large magnetic field (\textgreater 9 T)
is applied along the easy axis direction. Using the same technique, we are
also able to resolve a spin Seebeck effect from the paramagnetic phase of
geometrically frustrated antiferromagnet Gd$_{3}$Ga$_{5}$O$_{12}$
(gadolinium gallium garnet) and antiferromagnetic DyScO$_{3}$ (DSO). Since
these measurements occur above the ordering temperatures of these two
materials, short-range magnetic order is implicated as the cause of the spin
Seebeck effect in these systems. The discovery of the spin Seebeck effect in
these two materials classes suggest that both antiferromagnetic spin waves
and spin excitations from short range magnetic order may be used to generate
spin current from insulators and that the spin wave spectra of individual
materials are highly important to the specifics of the longitudinal spin
Seebeck effect. Since insulating antiferromagnets and paramagnets are far
more common than the typical insulating ferrimagnetic materials used in spin
Seebeck experiments, this discovery opens up a large new class of materials
for use in spin caloritronic devices.
All authors acknowledge support of the U.S. Department of Energy (DOE),
Office of Science, Basic Energy Sciences (BES), Materials Sciences and
Engineering Division. The use of facilities at the Center for Nanoscale
Materials, was supported by the U.S. DOE, BES under contract No.
DE-AC02-06CH11357.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.MAR.V19.1