Combined feedback and sympathetic cooling of a mechanical oscillator coupled to ultracold atoms

TL;DR

This paper demonstrates combined feedback and sympathetic cooling of a hybrid atomic-mechanical system, achieving near-ground state cooling of a membrane oscillator coupled to ultracold atoms, paving the way for advanced quantum technologies.

Contribution

It introduces a hybrid system with active feedback and sympathetic cooling, achieving near-ground state cooling of a membrane oscillator coupled to ultracold atoms.

Findings

Minimum mode occupation of n=16 achieved

Effective coupling characterized through sympathetic cooling

Combined cooling methods enable near-ground state preparation

Abstract

A promising route to novel quantum technologies are hybrid quantum systems, which combine the advantages of several individual quantum systems. We have realized a hybrid atomic-mechanical experiment consisting of a SiN membrane oscillator cryogenically precooled to 500 mK and optically coupled to a cloud of laser cooled Rb atoms. Here, we demonstrate active feedback cooling of the oscillator to a minimum mode occupation of n = 16 corresponding to a mode temperature of T = 200 {\mu}K. Furthermore, we characterize in detail the coupling of the membrane to the atoms by means of sympathetic cooling. By simultaneously applying both cooling methods we demonstrate the possibility of preparing the oscillator near the motional ground state while it is coupled to the atoms. Realistic modifications of our setup will enable the creation of a ground state hybrid quantum system, which opens the door for coherent quantum state transfer, teleportation and entanglement as well as quantum enhanced sensing applications.