Single-Photon-Level Atomic Frequency Comb Storage in Room Temperature Alkali Vapour

TL;DR

This paper demonstrates the coherent storage and retrieval of single-photon-level light in a room temperature rubidium vapor using the atomic frequency comb protocol, enabling quantum memory applications at ambient conditions.

Contribution

The work introduces a method for atomic frequency comb storage at room temperature with polarization independence, suitable for quantum information processing.

Findings

Achieved storage of weak coherent states with 6.59% efficiency.

Stored and recalled two temporal modes with 2.6% efficiency.

Demonstrated polarization-independent quantum memory capability.

Abstract

We have demonstrated the coherent storage and retrieval of single-photon-level light using the atomic frequency comb protocol in a room temperature rubidium vapour. Velocity-selective optical pumping is used to prepare the comb within the $F=2$ hyperfine ground state of rubidium, with the spacing between peaks coinciding with half the $F = 2 - F =3$ hyperfine splitting of the $5^2$P$_{3/2}$ excited state. Weak coherent states of average photon number $\mu_\mathrm{in} = 0.083(5)$ are stored with pre-programmed recall time of $7.5\,$ns with an efficiency of $\eta_{\textrm{AFC}} = 6.59(5)\,\%$, while two temporally distinct modes have been stored and recalled with $\eta_{\textrm{AFC}} = 2.6(1)\,\%$, allowing for time-bin qubit storage. Finally, the efficiency is observed to be independent of the input pulse polarisation, paving the way for polarisation qubit storage.