English

Passive Laser Power Stabilization via an Optical Spring

Optics 2022-06-01 v1

Abstract

Metrology experiments can be limited by the noise produced by the laser involved via small fluctuations in the laser's power or frequency. Typically, active power stabilization schemes consisting of an in-loop sensor and a feedback control loop are employed. Those schemes are fundamentally limited by shot noise coupling at the in-loop sensor. In this letter we propose to use the optical spring effect to passively stabilize the classical power fluctuations of a laser beam. In a proof of principle experiment, we show that the relative power noise of the laser is stabilized from approximately 2×1052 \times 10^{-5} Hz1/2^{-1/2} to a minimum value of 1.6×1071.6 \times 10^{-7} Hz1/2^{-1/2}, corresponding to the power noise reduction by a factor of 125125. The bandwidth at which stabilization occurs ranges from 400400 Hz to 100100 kHz. The work reported in this letter further paves the way for high power laser stability techniques which could be implemented in optomechanical experiments and in gravitational wave detectors.

Keywords

Cite

@article{arxiv.2204.00414,
  title  = {Passive Laser Power Stabilization via an Optical Spring},
  author = {Torrey Cullen and Scott Aronson and Ron Pagano and Marina Trad Nery and Henry Cain and Jonathon Cripe and Garret D. Cole and Safura Sharifi and Nancy Aggarwal and Benno Wilke and Thomas Corbitt},
  journal= {arXiv preprint arXiv:2204.00414},
  year   = {2022}
}
R2 v1 2026-06-24T10:34:39.260Z