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Hauptverfasser: Siegl, Luise, Schlitz, Richard, Youssef, Jamal Ben, Runge, Christian, Kamra, Akashdeep, Legrand, William, Huebl, Hans, Lammel, Michaela, Goennenwein, Sebastian T. B.
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2404.17327
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author Siegl, Luise
Schlitz, Richard
Youssef, Jamal Ben
Runge, Christian
Kamra, Akashdeep
Legrand, William
Huebl, Hans
Lammel, Michaela
Goennenwein, Sebastian T. B.
author_facet Siegl, Luise
Schlitz, Richard
Youssef, Jamal Ben
Runge, Christian
Kamra, Akashdeep
Legrand, William
Huebl, Hans
Lammel, Michaela
Goennenwein, Sebastian T. B.
contents State tomography allows to characterize quantum states, and was recently applied to reveal the dynamic magnetization state of a parametrically driven magnet. The identification of non-classical states, such as squeezed states, relies on a careful analysis of their emission and their distinction from thermal and vacuum fluctuations. A technique allowing to detect equilibrium magnetization fluctuations is a crucial first step in this regard. In this Letter, we show that inductive magnon noise spectroscopy (iMNS) allows to characterize the thermal magnetization fluctuations of a ferromagnetic thin film in a broadband coplanar waveguide-based scheme. Relative to a cold microwave background, the microwaves emitted by the equilibrium magnetization fluctuations can be detected via spectrum analysis. We provide a comprehensive picture of our microwave system by quantitatively modeling its response, including the thermalizing influence of the cables. The model allows for direct comparison to low-power broadband ferromagnetic resonance measurements with excellent agreement, corroborating the equilibrium character of the iMNS measurement by probing the linear response of the equilibrium state. Our work thus demonstrates broadband access to the equilibrium properties of magnetization fluctuations using a purely inductive approach.
format Preprint
id arxiv_https___arxiv_org_abs_2404_17327
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Inductive magnon noise spectroscopy
Siegl, Luise
Schlitz, Richard
Youssef, Jamal Ben
Runge, Christian
Kamra, Akashdeep
Legrand, William
Huebl, Hans
Lammel, Michaela
Goennenwein, Sebastian T. B.
Mesoscale and Nanoscale Physics
State tomography allows to characterize quantum states, and was recently applied to reveal the dynamic magnetization state of a parametrically driven magnet. The identification of non-classical states, such as squeezed states, relies on a careful analysis of their emission and their distinction from thermal and vacuum fluctuations. A technique allowing to detect equilibrium magnetization fluctuations is a crucial first step in this regard. In this Letter, we show that inductive magnon noise spectroscopy (iMNS) allows to characterize the thermal magnetization fluctuations of a ferromagnetic thin film in a broadband coplanar waveguide-based scheme. Relative to a cold microwave background, the microwaves emitted by the equilibrium magnetization fluctuations can be detected via spectrum analysis. We provide a comprehensive picture of our microwave system by quantitatively modeling its response, including the thermalizing influence of the cables. The model allows for direct comparison to low-power broadband ferromagnetic resonance measurements with excellent agreement, corroborating the equilibrium character of the iMNS measurement by probing the linear response of the equilibrium state. Our work thus demonstrates broadband access to the equilibrium properties of magnetization fluctuations using a purely inductive approach.
title Inductive magnon noise spectroscopy
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2404.17327