State-selective all-optical detection of Rydberg atoms

TL;DR

This paper introduces an all-optical method for detecting specific Rydberg states in ultracold alkali atoms by analyzing absorption signals, enabling state population and coherence measurement with potential quantum computing applications.

Contribution

The paper presents a novel all-optical detection protocol for Rydberg states that allows measurement of population and coherence without destructive techniques.

Findings

Successful proof-of-principle measurement on cold $^{87}$Rb atoms.

Detection scheme can infer initial Rydberg population from absorption curves.

Method is suitable for quantum computing protocols using Rydberg atoms.

Abstract

We present an all-optical protocol for detecting population in a selected Rydberg state of alkali atoms. The detection scheme is based on the interaction of an ensemble of ultracold atoms with two laser pulses: one weak probe pulse which is resonant with the transition between the ground state and the first excited state, and a pulse with high intensity which couples the first excited state to the selected Rydberg state. We show that by monitoring the absorption signal of the probe laser over time, one can deduce the initial population of the Rydberg state. Furthermore, it is shown that - for suitable experimental conditions - the dynamical absorption curve contains information on the initial coherence between the ground state and the selected Rydberg state. We present the results of a proof-of-principle measurement performed on a cold gas of $^{87}$Rb atoms. The method is expected to find application in quantum computing protocols based on Rydberg atoms.