Optimization of quantum noise in space gravitational-wave antenna DECIGO with optical-spring quantum locking considering mixture of vacuum fluctuations in homodyne detection

Quantum locking using optical spring and homodyne detection has been devised to reduce quantum noise that limits the sensitivity of DECIGO, a space-based gravitational wave antenna in the frequency band around 0.1 Hz for detection of primordial gravitational waves. The reduction in the upper limit o...

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Bibliographic Details
Published in:arXiv.org 2023-10
Main Authors: Tsuji, Kenji, Ishikawa, Tomohiro, Komori, Kentaro, Nagano, Koji, Enomoto, Yutaro, Michimura, Yuta, Umemura, Kurumi, Shimizu, Ryuma, Wu, Bin, Iwaguchi, Shoki, Kawasaki, Yuki, Furusawa, Akira, Kawamura, Seiji
Format: Article
Language:English
Subjects:
Configuration management
Design optimization
Design parameters
Frequencies
Gravitational wave antennas
Gravitational waves
Locking
Noise reduction
Noise sensitivity
Signal processing
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Summary:Quantum locking using optical spring and homodyne detection has been devised to reduce quantum noise that limits the sensitivity of DECIGO, a space-based gravitational wave antenna in the frequency band around 0.1 Hz for detection of primordial gravitational waves. The reduction in the upper limit of energy density \({\Omega}_{\mathrm{GW}}\) from \(2{\times}10^{-15}\) to \(1{\times}10^{-16}\), as inferred from recent observations, necessitates improved sensitivity in DECIGO to meet its primary science goals. To accurately evaluate the effectiveness of this method, this paper considers a detection mechanism that takes into account the influence of vacuum fluctuations on homodyne detection. In addition, an advanced signal processing method is devised to efficiently utilize signals from each photodetector, and design parameters for this configuration are optimized for the quantum noise. Our results show that this method is effective in reducing quantum noise, despite the detrimental impact of vacuum fluctuations on its sensitivity.
ISSN:2331-8422