Magnon-squeezing-enhanced weak magnetic field sensing in cavity-magnon system

• URL: http://arxiv.org/abs/2408.01905v2
• Date: Wed, 7 Aug 2024 04:20:12 GMT
• Title: Magnon-squeezing-enhanced weak magnetic field sensing in cavity-magnon system
• Authors: Zheng Liu, Yu-qiang Liu, Yi-jia Yang, Chang-shui Yu,
• Abstract summary: Quantum noise and thermal noise are the two primary sources of noise that limit the sensitivity of weak magnetic field sensing. We employ an anisotropic elliptical YIG sphere as a magnetic field probe to establish a parametric interaction of magnons and induce magnon squeezing effects. These effects can effectively suppress thermal noise in the magnon mode and amplify weak magnetic field signals from external sources.
• Score: 3.1592042828921505
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Quantum noise and thermal noise are the two primary sources of noise that limit the sensitivity of weak magnetic field sensing. Although quantum noise has been widely addressed, effectively reducing thermal noise remains challenging in detecting weak magnetic fields. We employ an anisotropic elliptical YIG sphere as a magnetic field probe to establish a parametric amplification interaction of magnons and induce magnon squeezing effects. These effects can effectively suppress thermal noise in the magnon mode and amplify weak magnetic field signals from external sources. Specifically, complete suppression of thermal noise can be achieved by placing the YIG sphere in a squeezed vacuum reservoir. Our scheme has the potential to inspire advancements in thermal noise suppression for quantum sensing.

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