Dissipative Quantum Feedback in Measurements Using a Parametrically Coupled Microcavity

TL;DR

This paper investigates how dissipative photon absorption in microcavities can induce quantum feedback, affecting optical and optomechanical measurements, with experimental observations revealing its impact on cavity dynamics and noise properties.

Contribution

It introduces the concept of dissipative quantum feedback via photon absorption in microcavities, demonstrating its effects on cavity susceptibility and measurement noise both theoretically and experimentally.

Findings

Dissipative absorption causes quantum feedback altering cavity response.

Experimental evidence of dissipative dynamics in optomechanical systems.

Dissipative feedback introduces excess noise and modifies cavity linewidth.

Abstract

Micro- and nanoscale optical or microwave cavities are used in a wide range of classical applications and quantum science experiments, ranging from precision measurements, laser technologies to quantum control of mechanical motion. The dissipative photon loss via absorption, present to some extent in any optical cavity, is known to introduce thermo-optical effects and thereby impose fundamental limits on precision measurements. Here, we theoretically and experimentally reveal that such dissipative photon absorption can result in quantum feedback via in-loop field detection of the absorbed optical field, leading to the intracavity field fluctuations to be squashed or antisquashed. Strikingly, this modifies the optical cavity susceptibility in coherent response measurements and causes excess noise and correlations in incoherent interferometric optomechanical measurements using a cavity. We experimentally observe such unanticipated dissipative dynamics in optomechanical spectroscopy of sideband-cooled optomechanical crystal cavitiess at both cryogenic temperature (approximately 8 K) and ambient conditions. The dissipative feedback introduces effective modifications to the optical cavity linewidth and the optomechanical scattering rate and gives rise to excess imprecision noise in the interferometric quantum measurement of mechanical motion. Such dissipative feedback differs fundamentally from a quantum nondemolition feedback, e.g., optical Kerr squeezing. The dissipative feedback itself always results in an antisqueezed out-of-loop optical field, while it can enhance the coexisting Kerr squeezing under certain conditions. Our result has wide-ranging implications for future dissipation engineering, such as dissipation enhanced sideband cooling and Kerr squeezing, quantum frequency conversion, and nonreciprocity in photonic systems.