Yuuki Sugiyama, Tomoya Shichijo, Nobuyuki Matsumoto, Akira Matsumura, Daisuke Miki, Kazuhiro Yamamoto
Dec 21, 2022
Pendulums have long been used as force sensors due to their ultimately low
dissipation (high-quality factor) characteristic. They are widely used in the
measurement of the gravitational constant, detection of gravitational waves,
and determination of ultralight dark matter. Furthermore, it is expected that
the quantum nature of gravity will be demonstrated by performing quantum
control for macroscopic pendulums. Recently, we have demonstrated that quantum
entanglement between two pendulums can be generated using an optical spring [D.
Miki, N. Matsumoto, A. Matsumura, T. Shichijo, Y. Sugiyama, K. Yamamoto, and N.
Yamamoto, arXiv:2210.13169 (2022)]; however, we have ignored that an optical
spring can reduce the quality factor (Q-factor) by applying normal-mode
splitting between the pendulum and rotational modes possessing relatively high
dissipation. Herein, we analyze a system composed of a cylinder suspended using
a beam (a suspended mirror, i.e., a pendulum) and an optical spring to consider
normal-mode splitting. The reduction in Q-factor is determined only by the beam
parameters: the ratio of the radius of the mirror to the length of the beam,
and the ratio of the frequency of the rotational mode to the pendulum mode in
the absence of cavity photons. In our analysis, we find that the reduction
factor $4.38$ is reproduced, which is consistent with the experimental result
in Matsumoto \textit{et al.} [N. Matsumoto, S. B.
Catan$\tilde{\text{o } }$-Lopez, M. Sugawara, S. Suzuki, N. Abe, K. Komori, Y.
Michimura, Y. Aso, and K. Edamatsu, Phys. Rev. Lett. 122, 071101 (2019)]. Our
analysis shows that low dissipation (high quality) can be reached using an
optical spring for the realistic pendulum system considering the rotational
degree of freedom.