Cavity cooling of an optically levitated nanoparticle

TL;DR

This paper demonstrates cavity cooling of a levitated nanoparticle in a standing-wave optical cavity, advancing the potential for room-temperature quantum control of mesoscopic objects and future quantum technologies.

Contribution

First experimental demonstration of cavity cooling of a levitated nanoparticle, showing potential for ground-state cooling at ultra-high vacuum levels.

Findings

Cooling rates suggest ground-state cooling is feasible with improved vacuum conditions.

Particle trapped at millibar vacuum levels and cooled via coherent scattering.

Paves the way for room-temperature quantum experiments with mesoscopic systems.

Abstract

The ability to trap and to manipulate individual atoms is at the heart of current implementations of quantum simulations, quantum computing, and long-distance quantum communication. Controlling the motion of larger particles opens up yet new avenues for quantum science, both for the study of fundamental quantum phenomena in the context of matter wave interference, and for new sensing and transduction applications in the context of quantum optomechanics. Specifically, it has been suggested that cavity cooling of a single nanoparticle in high vacuum allows for the generation of quantum states of motion in a room-temperature environment as well as for unprecedented force sensitivity. Here, we take the first steps into this regime. We demonstrate cavity cooling of an optically levitated nanoparticle consisting of approximately 10e9 atoms. The particle is trapped at modest vacuum levels of a few millibar in the standing-wave field of an optical cavity and is cooled through coherent scattering into the modes of the same cavity. We estimate that our cooling rates are sufficient for ground-state cooling, provided that optical trapping at a vacuum level of 10e-7 millibar can be realized in the future, e.g., by employing additional active-feedback schemes to stabilize the optical trap in three dimensions. This paves the way for a new light-matter interface enabling room-temperature quantum experiments with mesoscopic mechanical systems.