Directional Excitation of a High-Density Magnon Gas Using Coherently Driven Spin Waves

Brecht G. Simon; Samer Kurdi; Helena La; Iacopo Bertelli; Joris J. Carmiggelt; Maximilian Ruf; Nick De Jong; Hans Van Den Berg; Allard J. Katan; Toeno van der Sar

doi:10.1021/acs.nanolett.1c02654

Directional Excitation of a High-Density Magnon Gas Using Coherently Driven Spin Waves

Brecht G. Simon
, Samer Kurdi
, Helena La
, Iacopo Bertelli
, Joris J. Carmiggelt
, Maximilian Ruf
, Nick De Jong
, Hans Van Den Berg
, Allard J. Katan
, Toeno van der Sar^*

^*Corresponding author for this work

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

21 Citations (Scopus)

36 Downloads (Pure)

Abstract

Controlling magnon densities in magnetic materials enables driving spin transport in magnonic devices. We demonstrate the creation of large, out-of-equilibrium magnon densities in a thin-film magnetic insulator via microwave excitation of coherent spin waves and subsequent multimagnon scattering. We image both the coherent spin waves and the resulting incoherent magnon gas using scanning-probe magnetometry based on electron spins in diamond. We find that the gas extends unidirectionally over hundreds of micrometers from the excitation stripline. Surprisingly, the gas density far exceeds that expected for a boson system following a Bose-Einstein distribution with a maximum value of the chemical potential. We characterize the momentum distribution of the gas by measuring the nanoscale spatial decay of the magnetic stray fields. Our results show that driving coherent spin waves leads to a strong out-of-equilibrium occupation of the spin-wave band, opening new possibilities for controlling spin transport and magnetic dynamics in target directions.

Original language	English
Pages (from-to)	8213-8219
Number of pages	7
Journal	Nano Letters
Volume	21
Issue number	19
Early online date	1 Oct 2021
DOIs	https://doi.org/10.1021/acs.nanolett.1c02654
Publication status	Published - 13 Oct 2021

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

Keywords

Magnon gas
Nitrogen-vacancy centers
Scanning-probe magnetometry
Spin relaxometry
Spin waves
Yttrium iron garnet

ASJC Scopus subject areas

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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Cite this

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title = "Directional Excitation of a High-Density Magnon Gas Using Coherently Driven Spin Waves",

abstract = "Controlling magnon densities in magnetic materials enables driving spin transport in magnonic devices. We demonstrate the creation of large, out-of-equilibrium magnon densities in a thin-film magnetic insulator via microwave excitation of coherent spin waves and subsequent multimagnon scattering. We image both the coherent spin waves and the resulting incoherent magnon gas using scanning-probe magnetometry based on electron spins in diamond. We find that the gas extends unidirectionally over hundreds of micrometers from the excitation stripline. Surprisingly, the gas density far exceeds that expected for a boson system following a Bose-Einstein distribution with a maximum value of the chemical potential. We characterize the momentum distribution of the gas by measuring the nanoscale spatial decay of the magnetic stray fields. Our results show that driving coherent spin waves leads to a strong out-of-equilibrium occupation of the spin-wave band, opening new possibilities for controlling spin transport and magnetic dynamics in target directions.",

keywords = "Magnon gas, Nitrogen-vacancy centers, Scanning-probe magnetometry, Spin relaxometry, Spin waves, Yttrium iron garnet",

author = "Simon, \{Brecht G.\} and Samer Kurdi and Helena La and Iacopo Bertelli and Carmiggelt, \{Joris J.\} and Maximilian Ruf and \{De Jong\}, Nick and \{Van Den Berg\}, Hans and Katan, \{Allard J.\} and \{van der Sar\}, Toeno",

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year = "2021",

month = oct,

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doi = "10.1021/acs.nanolett.1c02654",

language = "English",

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T1 - Directional Excitation of a High-Density Magnon Gas Using Coherently Driven Spin Waves

AU - Simon, Brecht G.

AU - Kurdi, Samer

AU - La, Helena

AU - Bertelli, Iacopo

AU - Carmiggelt, Joris J.

AU - Ruf, Maximilian

AU - De Jong, Nick

AU - Van Den Berg, Hans

AU - Katan, Allard J.

AU - van der Sar, Toeno

PY - 2021/10/13

Y1 - 2021/10/13

N2 - Controlling magnon densities in magnetic materials enables driving spin transport in magnonic devices. We demonstrate the creation of large, out-of-equilibrium magnon densities in a thin-film magnetic insulator via microwave excitation of coherent spin waves and subsequent multimagnon scattering. We image both the coherent spin waves and the resulting incoherent magnon gas using scanning-probe magnetometry based on electron spins in diamond. We find that the gas extends unidirectionally over hundreds of micrometers from the excitation stripline. Surprisingly, the gas density far exceeds that expected for a boson system following a Bose-Einstein distribution with a maximum value of the chemical potential. We characterize the momentum distribution of the gas by measuring the nanoscale spatial decay of the magnetic stray fields. Our results show that driving coherent spin waves leads to a strong out-of-equilibrium occupation of the spin-wave band, opening new possibilities for controlling spin transport and magnetic dynamics in target directions.

AB - Controlling magnon densities in magnetic materials enables driving spin transport in magnonic devices. We demonstrate the creation of large, out-of-equilibrium magnon densities in a thin-film magnetic insulator via microwave excitation of coherent spin waves and subsequent multimagnon scattering. We image both the coherent spin waves and the resulting incoherent magnon gas using scanning-probe magnetometry based on electron spins in diamond. We find that the gas extends unidirectionally over hundreds of micrometers from the excitation stripline. Surprisingly, the gas density far exceeds that expected for a boson system following a Bose-Einstein distribution with a maximum value of the chemical potential. We characterize the momentum distribution of the gas by measuring the nanoscale spatial decay of the magnetic stray fields. Our results show that driving coherent spin waves leads to a strong out-of-equilibrium occupation of the spin-wave band, opening new possibilities for controlling spin transport and magnetic dynamics in target directions.

KW - Magnon gas

KW - Nitrogen-vacancy centers

KW - Scanning-probe magnetometry

KW - Spin relaxometry

KW - Spin waves

KW - Yttrium iron garnet

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SN - 1530-6984

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JO - Nano Letters

JF - Nano Letters

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ER -

Directional Excitation of a High-Density Magnon Gas Using Coherently Driven Spin Waves

Abstract

UN SDGs

Keywords

ASJC Scopus subject areas

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