Magnon Bose–Einstein Condensate and Supercurrents Over a Wide Temperature Range

L. Mihalceanu; D. Bozhko; V. Vasyuchka; A. A. Serga; B. Hillebrands; A. Pomyalov; V. L'vov; V. Tyberkevych

doi:10.15407/ujpe64.10.927

Magnon Bose–Einstein Condensate and Supercurrents Over a Wide Temperature Range

L. Mihalceanu, D. Bozhko, V. Vasyuchka, A. A. Serga, B. Hillebrands, A. Pomyalov, V. L'vov, V. Tyberkevych

Department of Chemical and Biological Physics

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

Magnon Bose–Einstein Condensates (BECs) and supercurrents are coherent quantum phenomena, which appear on a macroscopic scale in parametrically populated solid state spin systems. One of the most fascinating and attractive features of these processes is the possibility of magnon condensation and supercurrent excitation even at room temperature. At the same time, valuable information about a magnon BEC state, such as its lifetime, its formation threshold, and coherence, is provided by experiments at various temperatures. Here, we use Brillouin Light Scattering (BLS) spectroscopy for the investigation of the magnon BEC dynamics in a single-crystal film of yttrium iron garnet in a wide temperature range from 30 K to 380K. By comparing the BLS results with previous microwave measurements, we revealed the direct relation between the damping of the condensed and the parametrically injected magnons. The enhanced supercurrent dynamics was detected at 180 K near the minimum of BEC damping.

Original language	English
Pages (from-to)	927-932
Number of pages	6
Journal	Ukrainian Journal of Physics
Volume	64
Issue number	10
DOIs	https://doi.org/10.15407/ujpe64.10.927
Publication status	Published - 1 Nov 2019

Bibliographical note

Financial support by the European Research Coun-cil within the Advanced Grant No. 694709 “Super-Magnonics”, by Deutsche Forschungsgemeinschaft (DFG) within the Transregional Collaborative Re-search Center SFB/TR 49 “Condensed Matter Systems with Variable Many-Body Interactions”, by the DFG Project No. INST 248/178-1, and by the NSF of the USA grants Nos. EFMA-1641989 and ECCS-1708982 is gratefully acknowledged. D.A. Bozhko acknowledges the support from the Alexander von Humboldt Foundation. The authors are grateful to G.A. Melkov for the fruitful discussions.

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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title = "Magnon Bose–Einstein Condensate and Supercurrents Over a Wide Temperature Range",

abstract = "Magnon Bose–Einstein Condensates (BECs) and supercurrents are coherent quantum phenomena, which appear on a macroscopic scale in parametrically populated solid state spin systems. One of the most fascinating and attractive features of these processes is the possibility of magnon condensation and supercurrent excitation even at room temperature. At the same time, valuable information about a magnon BEC state, such as its lifetime, its formation threshold, and coherence, is provided by experiments at various temperatures. Here, we use Brillouin Light Scattering (BLS) spectroscopy for the investigation of the magnon BEC dynamics in a single-crystal film of yttrium iron garnet in a wide temperature range from 30 K to 380K. By comparing the BLS results with previous microwave measurements, we revealed the direct relation between the damping of the condensed and the parametrically injected magnons. The enhanced supercurrent dynamics was detected at 180 K near the minimum of BEC damping.",

author = "L. Mihalceanu and D. Bozhko and V. Vasyuchka and Serga, {A. A.} and B. Hillebrands and A. Pomyalov and V. L'vov and V. Tyberkevych",

note = "Financial support by the European Research Coun-cil within the Advanced Grant No. 694709 “Super-Magnonics”, by Deutsche Forschungsgemeinschaft (DFG) within the Transregional Collaborative Re-search Center SFB/TR 49 “Condensed Matter Systems with Variable Many-Body Interactions”, by the DFG Project No. INST 248/178-1, and by the NSF of the USA grants Nos. EFMA-1641989 and ECCS-1708982 is gratefully acknowledged. D.A. Bozhko acknowledges the support from the Alexander von Humboldt Foundation. The authors are grateful to G.A. Melkov for the fruitful discussions.",

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AU - Mihalceanu, L.

AU - Bozhko, D.

AU - Vasyuchka, V.

AU - Serga, A. A.

AU - Hillebrands, B.

AU - Pomyalov, A.

AU - L'vov, V.

AU - Tyberkevych, V.

N1 - Financial support by the European Research Coun-cil within the Advanced Grant No. 694709 “Super-Magnonics”, by Deutsche Forschungsgemeinschaft (DFG) within the Transregional Collaborative Re-search Center SFB/TR 49 “Condensed Matter Systems with Variable Many-Body Interactions”, by the DFG Project No. INST 248/178-1, and by the NSF of the USA grants Nos. EFMA-1641989 and ECCS-1708982 is gratefully acknowledged. D.A. Bozhko acknowledges the support from the Alexander von Humboldt Foundation. The authors are grateful to G.A. Melkov for the fruitful discussions.

PY - 2019/11/1

Y1 - 2019/11/1

N2 - Magnon Bose–Einstein Condensates (BECs) and supercurrents are coherent quantum phenomena, which appear on a macroscopic scale in parametrically populated solid state spin systems. One of the most fascinating and attractive features of these processes is the possibility of magnon condensation and supercurrent excitation even at room temperature. At the same time, valuable information about a magnon BEC state, such as its lifetime, its formation threshold, and coherence, is provided by experiments at various temperatures. Here, we use Brillouin Light Scattering (BLS) spectroscopy for the investigation of the magnon BEC dynamics in a single-crystal film of yttrium iron garnet in a wide temperature range from 30 K to 380K. By comparing the BLS results with previous microwave measurements, we revealed the direct relation between the damping of the condensed and the parametrically injected magnons. The enhanced supercurrent dynamics was detected at 180 K near the minimum of BEC damping.

AB - Magnon Bose–Einstein Condensates (BECs) and supercurrents are coherent quantum phenomena, which appear on a macroscopic scale in parametrically populated solid state spin systems. One of the most fascinating and attractive features of these processes is the possibility of magnon condensation and supercurrent excitation even at room temperature. At the same time, valuable information about a magnon BEC state, such as its lifetime, its formation threshold, and coherence, is provided by experiments at various temperatures. Here, we use Brillouin Light Scattering (BLS) spectroscopy for the investigation of the magnon BEC dynamics in a single-crystal film of yttrium iron garnet in a wide temperature range from 30 K to 380K. By comparing the BLS results with previous microwave measurements, we revealed the direct relation between the damping of the condensed and the parametrically injected magnons. The enhanced supercurrent dynamics was detected at 180 K near the minimum of BEC damping.

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Magnon Bose–Einstein Condensate and Supercurrents Over a Wide Temperature Range

Abstract

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