Quantum noise of a Michelson-Sagnac interferometer with translucent mechanical oscillator

TL;DR

This paper proposes a novel Michelson-Sagnac interferometer topology incorporating a translucent membrane to enhance quantum radiation pressure noise detection, enabling observation at feasible power and temperature conditions.

Contribution

It introduces a new interferometer design that allows quantum radiation pressure noise to be observed with low-reflectance membranes using signal-recycling techniques.

Findings

Quantum radiation pressure noise can be observed at 1 W power and 1 K temperature.

The proposed topology enables effective noise amplification despite low membrane reflectance.

Theoretical analysis confirms the feasibility of detecting quantum noise with current technology.

Abstract

Quantum fluctuations in the radiation pressure of light can excite stochastic motions of mechanical oscillators thereby realizing a linear quantum opto-mechanical coupling. When performing a precise measurement of the position of an oscillator, this coupling results in quantum radiation pressure noise. Up to now this effect has not been observed yet. Generally speaking, the strength of radiation pressure noise increases when the effective mass of the oscillator is decreased or when the power of the reflected light is increased. Recently, extremely light SiN membranes with high mechanical Q-values at room temperature have attracted attention as low thermal noise mechanical oscillators. However, the power reflectance of these membranes is much lower than unity which makes the use of advanced interferometer recycling techniques to amplify the radiation pressure noise in a standard Michelson interferometer inefficient. Here, we propose and theoretically analyze a Michelson-Sagnac interferometer that includes the membrane as a common end mirror for the Michelson interferometer part. In this new topology, both, power- and signal-recycling can be used even if the reflectance of the membrane is much lower than unity. In particular, signal-recycling is a useful tool because it does not involve a power increase at the membrane. We derive the formulas for the quantum radiation pressure noise and the shot-noise of an oscillator position measurement and compare them with theoretical models of the thermal noise of a SiN membrane with a fundamental resonant frequency of 75 kHz and an effective mass of 125 ng. We find that quantum radiation pressure noise should be observable with a power of 1 W at the central beam splitter of the interferometer and a membrane temperature of 1 K.