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Bose-Einstein condensation of quasiparticles by rapid cooling.

Michael SchneiderThomas BrächerDavid BreitbachViktor LauerPhilipp PirroDmytro A BozhkoHalyna Yu Musiienko-ShmarovaBjörn HeinzQi WangThomas MeyerFrank HeussnerSascha KellerEvangelos Th PapaioannouBert LägelThomas LöberCarsten DubsAndrei N SlavinVasyl S TiberkevichAlexander A SergaBurkard HillebrandsAndrii V Chumak
Published in: Nature nanotechnology (2020)
The fundamental phenomenon of Bose-Einstein condensation has been observed in different systems of real particles and quasiparticles. The condensation of real particles is achieved through a major reduction in temperature, while for quasiparticles, a mechanism of external injection of bosons by irradiation is required. Here, we present a new and universal approach to enable Bose-Einstein condensation of quasiparticles and to corroborate it experimentally by using magnons as the Bose-particle model system. The critical point to this approach is the introduction of a disequilibrium of magnons with the phonon bath. After heating to an elevated temperature, a sudden decrease in the temperature of the phonons, which is approximately instant on the time scales of the magnon system, results in a large excess of incoherent magnons. The consequent spectral redistribution of these magnons triggers the Bose-Einstein condensation.
Keyphrases
  • optical coherence tomography
  • magnetic resonance
  • ultrasound guided
  • contrast enhanced
  • diffusion weighted imaging
  • radiation induced
  • quantum dots