English

An optically trapped mirror for reaching the standard quantum limit

Optics 2015-06-19 v1 Systems and Control Quantum Physics

Abstract

The preparation of a mechanical oscillator driven by quantum back-action is a fundamental requirement to reach the standard quantum limit (SQL) for force measurement, in optomechanical systems. However, thermal fluctuating force generally dominates a disturbance on the oscillator. In the macroscopic scale, an optical linear cavity including a suspended mirror has been used for the weak force measurement, such as gravitational-wave detectors. This configuration has the advantages of reducing the dissipation of the pendulum (i.e., suspension thermal noise) due to a gravitational dilution by using a thin wire, and of increasing the circulating laser power. However, the use of the thin wire is weak for an optical torsional anti-spring effect in the cavity, due to the low mechanical restoring force of the wire. Thus, there is the trade-off between the stability of the system and the sensitivity. Here, we describe using a triangular optical cavity to overcome this limitation for reaching the SQL. The triangular cavity can provide a sensitive and stable system, because it can optically trap the mirror's motion of the yaw, through an optical positive torsional spring effect. To show this, we demonstrate a measurement of the torsional spring effect caused by radiation pressure forces.

Keywords

Cite

@article{arxiv.1405.4906,
  title  = {An optically trapped mirror for reaching the standard quantum limit},
  author = {Nobuyuki Matsumoto and Yuta Michimura and Yoichi Aso and Kimio Tsubono},
  journal= {arXiv preprint arXiv:1405.4906},
  year   = {2015}
}

Comments

9 pages, 6 figures. arXiv admin note: text overlap with arXiv:1312.5031

R2 v1 2026-06-22T04:18:26.188Z