Propagation of Spin-Wave Packets in Individual Nanosized Yttrium Iron Garnet Magnonic Conduits

Björn Heinz; Thomas Brächer; Michael Schneider; Qi Wang; Bert Lägel; Anna M. Friedel; David Breitbach; Steffen Steinert; Thomas Meyer; Martin Kewenig; Carsten Dubs; Philipp Pirro; Andrii V. Chumak

doi:10.1021/acs.nanolett.0c00657

Propagation of Spin-Wave Packets in Individual Nanosized Yttrium Iron Garnet Magnonic Conduits

Björn Heinz (Corresponding author)
, Thomas Brächer
, Michael Schneider
, Qi Wang
, Bert Lägel
, Anna M. Friedel
, David Breitbach
, Steffen Steinert
, Thomas Meyer
, Martin Kewenig
, Carsten Dubs
, Philipp Pirro
, Andrii V. Chumak

Nanomagnetism and Magnonics

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Modern-day CMOS-based computation technology is reaching its fundamental limitations. The emerging field of magnonics, which utilizes spin waves for data transport and processing, proposes a promising path to overcome these limitations. Different devices have been demonstrated recently on the macro- and microscale, but the feasibility of the magnonics approach essentially relies on the scalability of the structure feature size down to the extent of a few 10 nm, which are typical sizes for the established CMOS technology. Here, we present a study of propagating spin-wave packets in individual yttrium iron garnet (YIG) conduits with lateral dimensions down to 50 nm. Space and time-resolved microfocused Brillouin-light-scattering (BLS) spectroscopy is used to characterize the YIG nanostructures and measure the spin-wave decay length and group velocity directly. The revealed magnon transport at the scale comparable to the scale of CMOS proves the general feasibility of magnon-based data processing.

Original language	English
Pages (from-to)	4220-4227
Number of pages	8
Journal	Nano Letters
Volume	20
Issue number	6
DOIs	https://doi.org/10.1021/acs.nanolett.0c00657
Publication status	Published - 10 Jun 2020

Austrian Fields of Science 2012

103017 Magnetism
103009 Solid state physics

Keywords

beyond-CMOS
magnetic nanostructures
magnonics
spin waves
spintronics
yttrium iron garnet

Access to Document

10.1021/acs.nanolett.0c00657Licence: CC BY 4.0

Functional layers of nm-thick YIG films and microstructures
Chumak, A. (Project Lead), Levchenko, K. (Project Staff) & Knauer, S. (Affiliated Project Staff)
1/10/19 → 30/09/22
Project: Research funding
MagnonCircuits: Nano-Scale Magnonic Circuits for Novel Computing Systems
Chumak, A. (Project Lead), Wang, Q. (Project Staff), Knauer, S. (Scientific Project Staff) & Dobrovolskiy, O. (Scientific Project Staff)
1/06/16 → 30/11/21
Project: Research funding

Cite this

@article{5323cdc5b91f41f6aa8ccc349bf37b7a,

title = "Propagation of Spin-Wave Packets in Individual Nanosized Yttrium Iron Garnet Magnonic Conduits",

abstract = "Modern-day CMOS-based computation technology is reaching its fundamental limitations. The emerging field of magnonics, which utilizes spin waves for data transport and processing, proposes a promising path to overcome these limitations. Different devices have been demonstrated recently on the macro- and microscale, but the feasibility of the magnonics approach essentially relies on the scalability of the structure feature size down to the extent of a few 10 nm, which are typical sizes for the established CMOS technology. Here, we present a study of propagating spin-wave packets in individual yttrium iron garnet (YIG) conduits with lateral dimensions down to 50 nm. Space and time-resolved microfocused Brillouin-light-scattering (BLS) spectroscopy is used to characterize the YIG nanostructures and measure the spin-wave decay length and group velocity directly. The revealed magnon transport at the scale comparable to the scale of CMOS proves the general feasibility of magnon-based data processing.",

keywords = "beyond-CMOS, magnetic nanostructures, magnonics, spin waves, spintronics, yttrium iron garnet",

author = "Bj{\"o}rn Heinz and Thomas Br{\"a}cher and Michael Schneider and Qi Wang and Bert L{\"a}gel and Friedel, \{Anna M.\} and David Breitbach and Steffen Steinert and Thomas Meyer and Martin Kewenig and Carsten Dubs and Philipp Pirro and Chumak, \{Andrii V.\}",

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year = "2020",

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day = "10",

doi = "10.1021/acs.nanolett.0c00657",

language = "English",

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T1 - Propagation of Spin-Wave Packets in Individual Nanosized Yttrium Iron Garnet Magnonic Conduits

AU - Heinz, Björn

AU - Brächer, Thomas

AU - Schneider, Michael

AU - Wang, Qi

AU - Lägel, Bert

AU - Friedel, Anna M.

AU - Breitbach, David

AU - Steinert, Steffen

AU - Meyer, Thomas

AU - Kewenig, Martin

AU - Dubs, Carsten

AU - Pirro, Philipp

AU - Chumak, Andrii V.

PY - 2020/6/10

Y1 - 2020/6/10

N2 - Modern-day CMOS-based computation technology is reaching its fundamental limitations. The emerging field of magnonics, which utilizes spin waves for data transport and processing, proposes a promising path to overcome these limitations. Different devices have been demonstrated recently on the macro- and microscale, but the feasibility of the magnonics approach essentially relies on the scalability of the structure feature size down to the extent of a few 10 nm, which are typical sizes for the established CMOS technology. Here, we present a study of propagating spin-wave packets in individual yttrium iron garnet (YIG) conduits with lateral dimensions down to 50 nm. Space and time-resolved microfocused Brillouin-light-scattering (BLS) spectroscopy is used to characterize the YIG nanostructures and measure the spin-wave decay length and group velocity directly. The revealed magnon transport at the scale comparable to the scale of CMOS proves the general feasibility of magnon-based data processing.

AB - Modern-day CMOS-based computation technology is reaching its fundamental limitations. The emerging field of magnonics, which utilizes spin waves for data transport and processing, proposes a promising path to overcome these limitations. Different devices have been demonstrated recently on the macro- and microscale, but the feasibility of the magnonics approach essentially relies on the scalability of the structure feature size down to the extent of a few 10 nm, which are typical sizes for the established CMOS technology. Here, we present a study of propagating spin-wave packets in individual yttrium iron garnet (YIG) conduits with lateral dimensions down to 50 nm. Space and time-resolved microfocused Brillouin-light-scattering (BLS) spectroscopy is used to characterize the YIG nanostructures and measure the spin-wave decay length and group velocity directly. The revealed magnon transport at the scale comparable to the scale of CMOS proves the general feasibility of magnon-based data processing.

KW - beyond-CMOS

KW - magnetic nanostructures

KW - magnonics

KW - spin waves

KW - spintronics

KW - yttrium iron garnet

U2 - 10.1021/acs.nanolett.0c00657

DO - 10.1021/acs.nanolett.0c00657

M3 - Article

C2 - 32329620

AN - SCOPUS:85086345963

SN - 1530-6984

VL - 20

SP - 4220

EP - 4227

JO - Nano Letters

JF - Nano Letters

IS - 6

ER -

Propagation of Spin-Wave Packets in Individual Nanosized Yttrium Iron Garnet Magnonic Conduits

Abstract

Austrian Fields of Science 2012

Keywords

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Projects

Functional layers of nm-thick YIG films and microstructures

MagnonCircuits: Nano-Scale Magnonic Circuits for Novel Computing Systems

Cite this