Theoretical Detailed Analyses for DC readout and a Fabri-P\'erot gravitational-wave detector

TL;DR

This paper provides a detailed quantum analysis of a Fabry-Pérot gravitational-wave detector with DC readout, revealing that classical radiation pressure leakage prevents shot-noise reduction at high laser powers.

Contribution

It demonstrates that classical radiation pressure leakage affects shot-noise behavior and discusses how incomplete tuning impacts detector noise performance.

Findings

Shot-noise does not decrease with increased laser power due to radiation pressure leakage.

Adjusting the interferometer's tuning point can mitigate the effects of classical radiation pressure.

Incomplete tuning causes deviations in mirror displacements, affecting noise spectral density.

Abstract

The quantum expectation value and the stationary noise spectral density for a Fabry-P'erot gravitational-wave detector with a DC readout scheme are discussed in detail only through the quantum electrodynamics of lasers and the Heisenberg equations of mirrors' motion. We demonstrate that the initial conditions of the mirrors' motion concentrate around the fundamental frequency of the pendulum and are not related to the frequency range of our interest. Although, in the ideal case, there is consensus that the shot-noise contribution from the laser to the high-frequency range of the signal-referred noise spectral density decreases as the injected laser power increases, our derived noise spectral density shows that the shot-noise contribution does not decrease. This is due to leakage of classical radiation pressure forces from the carrier field to the output port, and the carrier field is used as the reference in the DC readout scheme. Since classical radiation pressure acts as a constant force, it shifts the pendulum's equilibrium point of the mirrors' motion. To recover the ideal case, we must consider adjusting the interferometer's tuning point to place the mirrors at their equilibrium positions. We investigate the case where the equilibrium tuning is incomplete and show that the behavior of the above shot noise is due to this incompleteness. We also discuss the maximum deviation of the mirror displacements from the equilibrium point during incomplete tuning to recover a near-ideal case.