O. Dzyapko scite author profile

Bose-Einstein condensation is one of the most fascinating phenomena predicted by quantum mechanics. It involves the formation of a collective quantum state composed of identical particles with integer angular momentum (bosons), if the particle density exceeds a critical value. To achieve Bose-Einstein condensation, one can either decrease the temperature or increase the density of bosons. It has been predicted that a quasi-equilibrium system of bosons could undergo Bose-Einstein condensation even at relatively high temperatures, if the flow rate of energy pumped into the system exceeds a critical value. Here we report the observation of Bose-Einstein condensation in a gas of magnons at room temperature. Magnons are the quanta of magnetic excitations in a magnetically ordered ensemble of magnetic moments. In thermal equilibrium, they can be described by Bose-Einstein statistics with zero chemical potential and a temperature-dependent density. In the experiments presented here, we show that by using a technique of microwave pumping it is possible to excite additional magnons and to create a gas of quasi-equilibrium magnons with a non-zero chemical potential. With increasing pumping intensity, the chemical potential reaches the energy of the lowest magnon state, and a Bose condensate of magnons is formed.

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Observation of Spontaneous Coherence in Bose-Einstein Condensate of Magnons

Demidov¹,

Dzyapko²,

Demokritov³

et al. 2008

Phys. Rev. Lett.

137

168

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The room-temperature dynamics of a magnon gas driven by short microwave pumping pulses is studied. An overpopulation of the lowest energy level of the system following the pumping is observed. Using the sensitivity of the Brillouin light scattering technique to the coherence degree of the scattering magnons we demonstrate the spontaneous emergence of coherence of the magnons at the lowest level, if their density exceeds a critical value. This finding is clear proof of the quantum nature of the observed phenomenon and direct evidence of Bose-Einstein condensation of magnons at room temperature.

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Controlled enhancement of spin-current emission by three-magnon splitting

Kurebayashi

Dzyapko²,

Demidov³

et al. 2011

Nature Mater

176

157

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Spin currents--the flow of angular momentum without the simultaneous transfer of electrical charge--play an enabling role in the field of spintronics. Unlike the charge current, the spin current is not a conservative quantity within the conduction carrier system. This is due to the presence of the spin-orbit interaction that couples the spin of the carriers to angular momentum in the lattice. This spin-lattice coupling acts also as the source of damping in magnetic materials, where the precessing magnetic moment experiences a torque towards its equilibrium orientation; the excess angular momentum in the magnetic subsystem flows into the lattice. Here we show that this flow can be reversed by the three-magnon splitting process and experimentally achieve the enhancement of the spin current emitted by the interacting spin waves. This mechanism triggers angular momentum transfer from the lattice to the magnetic subsystem and modifies the spin-current emission. The finding illustrates the importance of magnon-magnon interactions for developing spin-current based electronics.

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Thermalization of a Parametrically Driven Magnon Gas Leading to Bose-Einstein Condensation

et al. 2007

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The thermalization of parametrically pumped magnons caused by nonlinear multimagnon scattering processes and leading to the magnon Bose-Einstein condensation is investigated experimentally with high temporal resolution. The threshold pumping power necessary for the thermalization is determined. For pumping powers above this threshold the thermalization time has been found to decrease rapidly with power reaching the value down to 50 ns, which is much smaller than the magnon lifetime.

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Spatially non-uniform ground state and quantized vortices in a two-component Bose-Einstein condensate of magnons

Nowik-Boltyk¹,

Dzyapko²,

Demidov³

et al. 2012

Sci Rep

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A gas of magnons in magnetic films differs from all other known systems demonstrating Bose-Einstein condensation (BEC), since it possesses two energetically degenerate lowest-energy quantum states with non-zero wave vectors ±kBEC. Therefore, BEC in this system results in a spontaneously formed two-component Bose-Einstein condensate described by a linear combination of two spatially non-uniform wave-functions ∝exp(±ikBECz), while condensates found in other physical systems are characterized by spatially uniform wave-functions. Here we report a study of BEC of magnons with sub-micrometer spatial resolution. We experimentally confirm the existence of the two wave-functions and show that their interference results in a non-uniform ground state of the condensate with the density oscillating in space. Additionally, we observe stable topological defects in the condensate. By comparing the experimental results with predictions of a theoretical model based on the Ginzburg-Landau equation, we identify these defects as quantized vortices.

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Direct observation of Bose–Einstein condensation in a parametrically driven gas of magnons

et al. 2007

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Magnon Kinetics and Bose-Einstein Condensation Studied in Phase Space

et al. 2008

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Using a novel technique providing simultaneous resolution with respect to the wave vector and frequency of magnons, we observed the formation of a Bose-Einstein condensate documented by the narrowing of the magnon distribution in phase space. Based on the measured width of the distribution we determined the effective correlation length of the condensate, which appears to be anisotropic, reflecting the anisotropy of the magnon dispersion spectrum.

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Quantum coherence due to Bose–Einstein condensation of parametrically driven magnons

et al. 2008

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O. Dzyapko

Bose–Einstein condensation of quasi-equilibrium magnons at room temperature under pumping

Observation of Spontaneous Coherence in Bose-Einstein Condensate of Magnons

Controlled enhancement of spin-current emission by three-magnon splitting

Thermalization of a Parametrically Driven Magnon Gas Leading to Bose-Einstein Condensation

Spatially non-uniform ground state and quantized vortices in a two-component Bose-Einstein condensate of magnons

Direct observation of Bose–Einstein condensation in a parametrically driven gas of magnons

Magnon Kinetics and Bose-Einstein Condensation Studied in Phase Space

Quantum coherence due to Bose–Einstein condensation of parametrically driven magnons

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