21 research outputs found
Hybrid Magnonic Reservoir Computing
Magnonic systems have been a major area of research interest due to their
potential benefits in speed and lower power consumption compared to traditional
computing. One particular area that they may be of advantage is as Physical
Reservoir Computers in machine learning models. In this work, we build on an
established design for using an Auto-Oscillation Ring as a reservoir computer
by introducing a simple neural network midstream and introduce an additional
design using a spin wave guide with a scattering regime for processing data
with different types of inputs. We simulate these designs on the new micro
magnetic simulation software, Magnum.np, and show that the designs are capable
of performing on various real world data sets comparably or better than
traditional dense neural networks
Low-damping transmission of spin waves through YIG/Pt-based layered structures for spin-orbit-torque applications
We show that in YIG-Pt bi-layers, which are widely used in experiments on the
spin transfer torque and spin Hall effects, the spin-wave amplitude
significantly decreases in comparison to a single YIG film due to the
excitation of microwave eddy currents in a Pt coat. By introducing a novel
excitation geometry, where the Pt layer faces the ground plane of a microstrip
line structure, we suppressed the excitation of the eddy currents in the Pt
layer and, thus, achieved a large increase in the transmission of the
Damon-Eshbach surface spin wave. At the same time, no visible influence of an
external dc current applied to the Pt layer on the spin-wave amplitude in the
YIG-Pt bi-layer was observed in our experiments with YIG films of micrometer
thickness
Double accumulation and anisotropic transport of magneto-elastic bosons in yttrium iron garnet films
Interaction between quasiparticles of a different nature, such as magnons and
phonons in a magnetic medium, leads to the mixing of their properties and the
formation of hybrid states in the areas of intersection of individual spectral
branches. We recently reported the discovery of a new phenomenon mediated by
the magnon-phonon interaction: the spontaneous bottleneck accumulation of
magneto-elastic bosons under electromagnetic pumping of pure magnons into a
ferrimagnetic yttrium iron garnet film. Here, by studying the transport
properties of the accumulated magneto-elastic bosons, we reveal that such
accumulation occurs in two frequency-distant groups of quasiparticles:
quasi-phonons and quasi-magnons. They propagate with different speeds in
different directions relative to the magnetization field. The theoretical model
we propose qualitatively describes the double accumulation effect, and the
analysis of the two-dimensional spectrum of quasiparticles in the hybridization
region allows us to determine the wavevectors and frequencies of each of the
groups
Temperature dependent relaxation of dipole-exchange magnons in yttrium iron garnet films
Low energy consumption enabled by charge-free information transport, which is
free from ohmic heating, and the ability to process phase-encoded data by
nanometer-sized interference devices at GHz and THz frequencies are just a few
benefits of spin-wave-based technologies. Moreover, when approaching cryogenic
temperatures, quantum phenomena in spin-wave systems pave the path towards
quantum information processing. In view of these applications, the lifetime of
magnonsspin-wave quantais of high relevance for the fields of magnonics,
magnon spintronics and quantum computing. Here, the relaxation behavior of
parametrically excited magnons having wavenumbers from zero up to was experimentally investigated in the temperature range
from 20 K to 340 K in single crystal yttrium iron garnet (YIG) films
epitaxially grown on gallium gadolinium garnet (GGG) substrates as well as in a
bulk YIG crystalthe magnonic materials featuring the lowest magnetic damping
known so far. As opposed to the bulk YIG crystal in YIG films we have found a
significant increase in the magnon relaxation rate below 150 Kup to 10.5
times the reference value at 340 Kin the entire range of probed wavenumbers.
This increase is associated with rare-earth impurities contaminating the YIG
samples with a slight contribution caused by coupling of spin waves to the spin
system of the paramagnetic GGG substrate at the lowest temperatures
Tunable space-time crystal in room-temperature magnetodielectrics
We report the experimental realization of a space-time crystal with tunable
periodicity in time and space in the magnon Bose-Einstein Condensate (BEC),
formed in a room-temperature Yttrium Iron Garnet (YIG) film by radio-frequency
space-homogeneous magnetic field. The magnon BEC is prepared to have a well
defined frequency and non-zero wavevector. We demonstrate how the crystalline
"density" as well as the time and space textures of the resulting crystal may
be tuned by varying the experimental parameters: external static magnetic
field, temperature, thickness of the YIG film and power of the radio-frequency
field. The proposed space-time crystals provide a new dimension for exploring
dynamical phases of matter and can serve as a model nonlinear Floquet system,
that brings in touch the rich fields of classical nonlinear waves, magnonics
and periodically driven systems
Microwave magnon damping in YIG films at millikelvin temperatures
Magnon systems used in quantum devices require low damping if coherence is to
be maintained. The ferrimagnetic electrical insulator yttrium iron garnet (YIG)
has low magnon damping at room temperature and is a strong candidate to host
microwave magnon excitations in future quantum devices. Monocrystalline YIG
films are typically grown on gadolinium gallium garnet (GGG) substrates. In
this work, comparative experiments made on YIG waveguides with and without GGG
substrates indicate that the material plays a significant role in increasing
the damping at low temperatures. Measurements reveal that damping due to
temperature-peak processes is dominant above 1 K. Damping behaviour that we
show can be attributed to coupling to two-level fluctuators (TLFs) is observed
below 1 K. Upon saturating the TLFs in the substrate-free YIG at 20 mK,
linewidths of 1.4 MHz are achievable: lower than those measured at room
temperature.Comment: 5 pages, 4 figure
Bose-Einstein condensation in systems with flux equilibrium
We consider flux equilibrium in dissipative nonlinear wave systems subject to
external energy pumping. In such systems, the elementary excitations, or
quasiparticles, can create a Bose-Einstein condensate. We develop a theory on
the Bose-Einstein condensation of quasiparticles for various regimes of
external excitation, ranging from weak and stationary to ultra-strong pumping,
enabling us to determine the number of quasiparticles near the bottom of the
energy spectrum and their distribution along wave vectors. We identify physical
phenomena leading to condensation in each of the regimes. For weak stationary
pumping, where the distribution of quasiparticles deviates only slightly from
thermodynamic equilibrium, we define a range of pumping parameters where the
condensation occurs and estimate the density of the condensate and the fraction
of the condensed quasiparticles. As the pumping amplitude increases, a powerful
influx of injected quasiparticles is created by the Kolmogorov-Zakharov
scattering cascade, leading to their Bose-Einstein condensation. With even
stronger pumping, kinetic instability may occur, resulting in a direct transfer
of injected quasiparticles to the bottom of the spectrum. For the case of
ultra-strong parametric pumping, we have developed a stationary nonlinear
theory of kinetic instability. The theory agrees qualitatively with
experimental data obtained using Brillouin light scattering spectroscopy during
parametric pumping of magnons in room-temperature films of yttrium-iron garnet.Comment: 25 pages, 14 figure