Bose-Einstein condensation of quasiparticles by rapid cooling

Michael Schneider; Thomas Brächer; David Breitbach; Viktor Lauer; Philipp Pirro; Dmytro A. Bozhko; Halyna Yu. Musiienko-Shmarova; Björn Heinz; Qi Wang; Thomas Meyer; Frank Heussner; Sascha Keller; Evangelos Th. Papaioannou; Bert Lägel; Thomas Löber; Carsten Dubs; Andrei N. Slavin; Vasyl S. Tiberkevich; Alexander A. Serga; Burkard Hillebrands; Andrii Chumak

doi:10.1038/s41565-020-0671-z

Bose-Einstein condensation of quasiparticles by rapid cooling

Michael Schneider (Corresponding author)
, Thomas Brächer
, David Breitbach
, Viktor Lauer
, Philipp Pirro
, Dmytro A. Bozhko
, Halyna Yu. Musiienko-Shmarova
, Björn Heinz
, Qi Wang
, Thomas Meyer
, Frank Heussner
, Sascha Keller
, Evangelos Th. Papaioannou
, Bert Lägel
, Thomas Löber
, Carsten Dubs
, Andrei N. Slavin
, Vasyl S. Tiberkevich
, Alexander A. Serga
, Burkard Hillebrands

Andrii Chumak (Corresponding author)

Nanomagnetism and Magnonics

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

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.

Original language	English
Pages (from-to)	457–461
Number of pages	5
Journal	Nature Nanotechnology
Volume	15
DOIs	https://doi.org/10.1038/s41565-020-0671-z
Publication status	Published - 20 Apr 2020

Funding

This research was funded by ERC Starting Grant 678309 MagnonCircuits and ERC Advanced Grant 694709 Super-Magnonics, as well as by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) TRR 173-268565370 and Project DU 1427/2-1, by grants no. EFMA-1641989 and no. ECCS-1708982 from the National Science Foundation of the United States, and by the U.S. AFOSR under the MURI grant #FA9550-19-1-0307.

Austrian Fields of Science 2012

103015 Condensed matter

Keywords

ROOM-TEMPERATURE
MAGNONS

Access to Document

10.1038/s41565-020-0671-z

https://arxiv.org/abs/1612.07305Licence: Unspecified

Cite this

Schneider, M., Brächer, T., Breitbach, D., Lauer, V., Pirro, P., Bozhko, D. A., Musiienko-Shmarova, H. Y., Heinz, B., Wang, Q., Meyer, T., Heussner, F., Keller, S., Papaioannou, E. T., Lägel, B., Löber, T., Dubs, C., Slavin, A. N., Tiberkevich, V. S., Serga, A. A., ... Chumak, A. (2020). Bose-Einstein condensation of quasiparticles by rapid cooling. Nature Nanotechnology, 15, 457–461. https://doi.org/10.1038/s41565-020-0671-z

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title = "Bose-Einstein condensation of quasiparticles by rapid cooling",

abstract = "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.",

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author = "Michael Schneider and Thomas Br{\"a}cher and David Breitbach and Viktor Lauer and Philipp Pirro and Bozhko, \{Dmytro A.\} and Musiienko-Shmarova, \{Halyna Yu.\} and Bj{\"o}rn Heinz and Qi Wang and Thomas Meyer and Frank Heussner and Sascha Keller and Papaioannou, \{Evangelos Th.\} and Bert L{\"a}gel and Thomas L{\"o}ber and Carsten Dubs and Slavin, \{Andrei N.\} and Tiberkevich, \{Vasyl S.\} and Serga, \{Alexander A.\} and Burkard Hillebrands and Andrii Chumak",

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doi = "10.1038/s41565-020-0671-z",

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Schneider, M, Brächer, T, Breitbach, D, Lauer, V, Pirro, P, Bozhko, DA, Musiienko-Shmarova, HY, Heinz, B, Wang, Q, Meyer, T, Heussner, F, Keller, S, Papaioannou, ET, Lägel, B, Löber, T, Dubs, C, Slavin, AN, Tiberkevich, VS, Serga, AA, Hillebrands, B & Chumak, A 2020, 'Bose-Einstein condensation of quasiparticles by rapid cooling', Nature Nanotechnology, vol. 15, pp. 457–461. https://doi.org/10.1038/s41565-020-0671-z

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T1 - Bose-Einstein condensation of quasiparticles by rapid cooling

AU - Schneider, Michael

AU - Brächer, Thomas

AU - Breitbach, David

AU - Lauer, Viktor

AU - Pirro, Philipp

AU - Bozhko, Dmytro A.

AU - Musiienko-Shmarova, Halyna Yu.

AU - Heinz, Björn

AU - Wang, Qi

AU - Meyer, Thomas

AU - Heussner, Frank

AU - Keller, Sascha

AU - Papaioannou, Evangelos Th.

AU - Lägel, Bert

AU - Löber, Thomas

AU - Dubs, Carsten

AU - Slavin, Andrei N.

AU - Tiberkevich, Vasyl S.

AU - Serga, Alexander A.

AU - Hillebrands, Burkard

AU - Chumak, Andrii

PY - 2020/4/20

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N2 - 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.

AB - 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.

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KW - MAGNONS

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EP - 461

JO - Nature Nanotechnology

JF - Nature Nanotechnology

ER -

Bose-Einstein condensation of quasiparticles by rapid cooling

Abstract

Funding

Austrian Fields of Science 2012

Keywords

Access to Document

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Functional layers of nm-thick YIG films and microstructures

MagnonCircuits: Nano-Scale Magnonic Circuits for Novel Computing Systems

Cite this

Bose-Einstein condensation of quasiparticles by rapid cooling

Abstract

Funding

Austrian Fields of Science 2012

Keywords

Access to Document

Other files and links

Fingerprint

Projects

Functional layers of nm-thick YIG films and microstructures

MagnonCircuits: Nano-Scale Magnonic Circuits for Novel Computing Systems

Cite this