Transmitting squeezed states in a cascaded cavity-magnonic system

Zhi Bo Yang; Rong Can Yang; Shutian Liu

doi:10.1364/OE.551766

Transmitting squeezed states in a cascaded cavity-magnonic system

Zhi Bo Yang
, Rong Can Yang
, Shutian Liu^*

^*Corresponding author for this work

School of Physics, Harbin Institute of Technology
Fujian Normal University

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

1 Scopus citations

Abstract

The squeezed state has wide applications in quantum information and metrology. This work demonstrates the long-distance transmission of a squeezed state, where we utilize a cavity-magnonic system composed of a cascaded cavity and a yttrium iron garnet sphere. The squeezed source, originating from a flux-driven Josephson parametric amplifier, is mediated through six cavity modes and ultimately transmitted to magnon mode. With appropriate detuning matching, state transmission can be blocked at any mode, and the difference in squeezing phase between adjacent modes is π. Squeezed magnons exhibit high robustness against environmental temperature and magnetic damping. Our work provides prior guidance for multi-mode transmission of quantum states in continuous variable systems.

Original language	English
Pages (from-to)	4725-4734
Number of pages	10
Journal	Optics Express
Volume	33
Issue number	3
DOIs	https://doi.org/10.1364/OE.551766
State	Published - 10 Feb 2025
Externally published	Yes

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title = "Transmitting squeezed states in a cascaded cavity-magnonic system",

abstract = "The squeezed state has wide applications in quantum information and metrology. This work demonstrates the long-distance transmission of a squeezed state, where we utilize a cavity-magnonic system composed of a cascaded cavity and a yttrium iron garnet sphere. The squeezed source, originating from a flux-driven Josephson parametric amplifier, is mediated through six cavity modes and ultimately transmitted to magnon mode. With appropriate detuning matching, state transmission can be blocked at any mode, and the difference in squeezing phase between adjacent modes is π. Squeezed magnons exhibit high robustness against environmental temperature and magnetic damping. Our work provides prior guidance for multi-mode transmission of quantum states in continuous variable systems.",

author = "Yang, \{Zhi Bo\} and Yang, \{Rong Can\} and Shutian Liu",

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AU - Liu, Shutian

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N2 - The squeezed state has wide applications in quantum information and metrology. This work demonstrates the long-distance transmission of a squeezed state, where we utilize a cavity-magnonic system composed of a cascaded cavity and a yttrium iron garnet sphere. The squeezed source, originating from a flux-driven Josephson parametric amplifier, is mediated through six cavity modes and ultimately transmitted to magnon mode. With appropriate detuning matching, state transmission can be blocked at any mode, and the difference in squeezing phase between adjacent modes is π. Squeezed magnons exhibit high robustness against environmental temperature and magnetic damping. Our work provides prior guidance for multi-mode transmission of quantum states in continuous variable systems.

AB - The squeezed state has wide applications in quantum information and metrology. This work demonstrates the long-distance transmission of a squeezed state, where we utilize a cavity-magnonic system composed of a cascaded cavity and a yttrium iron garnet sphere. The squeezed source, originating from a flux-driven Josephson parametric amplifier, is mediated through six cavity modes and ultimately transmitted to magnon mode. With appropriate detuning matching, state transmission can be blocked at any mode, and the difference in squeezing phase between adjacent modes is π. Squeezed magnons exhibit high robustness against environmental temperature and magnetic damping. Our work provides prior guidance for multi-mode transmission of quantum states in continuous variable systems.

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JF - Optics Express

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ER -

Transmitting squeezed states in a cascaded cavity-magnonic system

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