Active-feedback quantum control of an integrated low-frequency mechanical resonator

TL;DR

This paper demonstrates measurement-based feedback cooling of an integrated optomechanical resonator in the sideband-unresolved regime, achieving near-quantum ground state occupation and verifying quantum motion at different bath temperatures.

Contribution

It introduces a fully integrated optomechanical device operating in the sideband-unresolved limit with measurement-based feedback cooling, achieving near-quantum ground state occupation.

Findings

Achieved a minimal phonon occupation of 0.76 with helium cooling.

Achieved a phonon occupation of 3.5 with nitrogen cooling.

Verified quantum character through sideband asymmetry.

Abstract

Preparing a massive mechanical resonator in a state with quantum limited motional energy provides a promising platform for studying fundamental physics with macroscopic systems and allows to realize a variety of applications, including precise sensing. While several demonstrations of such ground-state cooled systems have been achieved, in particular in sideband-resolved cavity optomechanics, for many systems overcoming the heating from the thermal bath remains a major challenge. In contrast, optomechanical systems in the sideband-unresolved limit are much easier to realize due to the relaxed requirements on their optical properties, and the possibility to use a feedback control schemes to reduce the motional energy. The achievable thermal occupation is ultimately limited by the correlation between the measurement precision and the back-action from the measurement. Here, we demonstrate measurement-based feedback cooling on a fully integrated optomechanical device fabricated using a pick-and-place method, operating in the deep sideband-unresolved limit. With the large optomechanical interaction and a low thermal decoherence rate, we achieve a minimal average phonon occupation of 0.76 when pre-cooled with liquid helium and 3.5 with liquid nitrogen. Significant sideband asymmetry for both bath temperatures verifies the quantum character of the mechanical motion. Our method and device are ideally suited for sensing applications directly operating at the quantum limit, greatly simplifying the operation of an optomechanical system in this regime.