75 research outputs found
Mechanisms of nonlinear spin-wave emission from a microwave driven nanocontact
We present a micromagnetic study of linear and nonlinear spin-wave modes
excited in an extended permalloy thin film by a microwave driven nanocontact.
We show that the linear mode having the frequency equal to the excitation
frequency (f) is driven by the ac Oersted field component perpendicular to the
static external field (applied in-plane of the sample). The nonlinear mode with
the frequency f /2 is excited as an independent eigenmode within a parametric
longitudinal pumping process (due ac Oersted field component parallel to the
bias field). Spectral positions of those modes are determined both in the space
and phase domain. The results are important for the transfer of information
coded into spin-waves between nanocontacts, and for synchronization of spin
transfer torque nano-oscillators.Comment: 5 pages, 4 figure
Spintronic logic: from transducers to logic gates and circuits
While magnetic solid-state memory has found commercial applications to date,
magnetic logic has rather remained on a conceptual level so far. Here, we
discuss open challenges of different spintronic logic approaches, which use
magnetic excitations for computation. While different logic gate designs have
been proposed and proof of concept experiments have been reported, no
nontrivial operational spintronic circuit has been demonstrated due to many
open challenges in spintronic circuit and system design. Furthermore, the
integration of spintronic circuits in CMOS systems will require the usage of
transducers between the electric (CMOS) and magnetic domains. We show that
these transducers can limit the performance as well as the energy consumption
of hybrid CMOS-spintronic systems. Hence, the optimization of transducer
efficiency will be a major step towards competitive spintronic logic system.Comment: This work has received funding from the European Union's Horizon 2020
research and innovation program within the project CHIRON (grant agreement
no. 801055) as well as from the Horizon Europe research and innovation
program within the project SPIDER (grant agreement no. 101070417
Spin wave emission by spin-orbit torque antennas
We study the generation of propagating spin waves in Ta/CoFeB waveguides by
spin-orbit torque antennas and compare them to conventional inductive antennas.
The spin-orbit torque was generated by a transverse microwave current across
the magnetic waveguide. The detected spin wave signals for an in-plane
magnetization across the waveguide (Damon-Eshbach configuration) exhibited the
expected phase rotation and amplitude decay upon propagation when the current
spreading was taken into account. Wavevectors up to about 6 rad/m could be
excited by the spin-orbit torque antennas despite the current spreading,
presumably due to the non-uniformity of the microwave current. The relative
magnitude of generated anti-damping spin-Hall and Oersted fields was calculated
within an analytic model and it was found that they contribute approximately
equally to the total effective field generated by the spin-orbit torque
antenna. Due to the ellipticity of the precession in the ultrathin waveguide
and the different orientation of the anti-damping spin-Hall and Oersted fields,
the torque was however still dominated by the Oersted field. The prospects for
obtaining a pure spin-orbit torque response are discussed, as are the energy
efficiency and the scaling properties of spin-orbit torque antennas.Comment: 20 pages, 5 figure
Excitation and propagation of spin waves in non-uniformly magnetized waveguides
The characteristics of spin waves in ferromagnetic waveguides with nonuniform
magnetization have been investigated for situations where the shape anisotropy
field of the waveguide is comparable to the external bias field. Spin-wave
generation was realized by the magnetoelastic effect by applying normal and
shear strain components, as well as by the Oersted field emitted by an
inductive antenna. The magnetoelastic excitation field has a nonuniform profile
over the width of the waveguide because of the nonuniform magnetization
orientation, whereas the Oersted field remains uniform. Using micromagnetic
simulations, we indicate that both types of excitation fields generate
quantised width modes with both odd and even mode numbers as well as tilted
phase fronts. We demonstrate that these effects originate from the average
magnetization orientation with respect to the main axes of the magnetic
waveguide. Furthermore, it is indicated that the excitation efficiency of the
second-order mode generally surpasses that of the first-order mode due to their
symmetry. The relative intensity of the excited modes can be controlled by the
strain state as well as by tuning the dimensions of the excitation area.
Finally, we demonstrate that the nonreciprocity of spin-wave radiation due to
the chirality of an Oersted field generated by an inductive antenna is absent
for magnetoelastic spin-wave excitation.Comment: 22 pages, 8 figure
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