8 research outputs found
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
Confinement of Bose-Einstein magnon condensates in adjustable complex magnetization landscapes
Coherent wave states such as Bose-Einstein condensates (BECs), which
spontaneously form in an overpopulated magnon gas even at room temperature,
have considerable potential for wave-based computing and information processing
at microwave frequencies. The ability to control the transport properties of
magnon BECs plays an essential role for their practical use. Here, we
demonstrate spatio-temporal control of the BEC density distribution through the
excitation of magnon supercurrents in an inhomogeneously magnetized yttrium
iron garnet film. The BEC is created by microwave parametric pumping and probed
by Brillouin light scattering spectroscopy. The desired magnetization profile
is prepared by heating the film with optical patterns projected onto its
surface using a phase-based wavefront modulation technique. Specifically, we
observe a pronounced spatially localized magnon accumulation caused by magnon
supercurrents flowing toward each other originating in two heated regions. This
accumulation effect increases the BEC lifetime due to the constant influx of
condensed magnons into the confinement region. The shown approach to manipulate
coherent waves provides an opportunity to extend the lifetime of freely
evolving magnon BECs, create dynamic magnon textures, and study the interaction
of magnon condensates formed in different regions of the sample.Comment: 8 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
Long-distance supercurrent transport in a room-temperature Bose-Einstein magnon condensate
The term supercurrent relates to a macroscopic dissipation-free collective
motion of a quantum condensate and is commonly associated with such famous
low-temperature phenomena as superconductivity and superfluidity. Another type
of motion of quantum condensates is second sound - a wave of the density of a
condensate. Recently, we reported on an enhanced decay of a parametrically
induced Bose-Einstein condensate (BEC) of magnons caused by a supercurrent
outflow of the BEC phase from the locally heated area of a room temperature
magnetic film. Here, we present the direct experimental observation of a
long-distance spin transport in such a system. The condensed magnons being
pushed out from the potential well within the heated area form a density wave,
which propagates through the BEC many hundreds of micrometers in the form of a
specific second sound pulse - Bogoliubov waves - and is reflected from the
sample edge. The discovery of the long distance supercurrent transport in the
magnon BEC further advances the frontier of the physics of quasiparticles and
allows for the application of related transport phenomena for low-loss data
transfer in perspective magnon spintronics devices
Experimental observation of Josephson oscillations in a room-temperature Bose-Einstein magnon condensate
The alternating current (ac) Josephson effect in a time-independent
spatially-inhomogeneous setting is manifested by the occurrence of Josephson
oscillations - periodic macroscopic phase-induced collective motions of the
quantum condensate. So far, this phenomenon was observed at cryogenic
temperatures in superconductors, in superfluid helium, and in Bose-Einstein
condensates (BECs) of trapped atoms. Here, we report on the discovery of the ac
Josephson effect in a magnon BEC carried by a room-temperature ferrimagnetic
film. The BEC is formed in a parametrically populated magnon gas in the spatial
vicinity of a magnetic trench created by a dc electric current. The appearance
of the Josephson effect is manifested by oscillations of the magnon BEC density
in the trench, caused by a coherent phase shift between this BEC and the BEC in
the nearby regions. Our findings advance the physics of room-temperature
macroscopic quantum phenomena and will allow for their application for data
processing in magnon spintronics devices
Substituted hippurates and hippurate analogs as substrates and inhibitors of peptidylglycine a-hydroxylating monooxygenase (PHM)
Peptidyl a-hydroxylating monooxygenase (PHM) functions in vivo towards the biosynthesis of a-amidated peptide hormones in mammals and insects. PHM is a potential target for the development of inhibitors as drugs for the treatment of human disease and as insecticides for the management of insect pests. We show here that relatively simple ground state analogs of the PHM substrate hippuric acid (C6H5-CO-NH-CH2-COOH) inhibit the enzyme with Ki values as low as 0.5 µM. Substitution of sulfur atom(s) into the hippuric acid analog increases the affinity of PHM for the inhibitor. Replacement of the acetylglycine moiety, -CO-NH-CH2-COOH with an S-(thioacetyl)thioglycolic acid moiety, -CS-S-CH2-COOH, yields compounds with the highest PHM affinity. Both S-(2-phenylthioacetyl)thioglycolate and S-(4-ethylthiobenzoyl)thioglycolic acid inhibit the proliferation of cultured human prostate cancer cells at concentrations >100-fold excess of their respective Ki values. Comparison of Ki values between mammalian PHM and insect PHM shows differences in potency suggesting that a PHM-based insecticide with limited human toxicity can be developed. © 2008 Elsevier Ltd. All rights reserved