Quantum optical experiments towards atom-photon entanglement

TL;DR

This paper reports the experimental creation of entanglement between a single atom and a photon, demonstrating high-fidelity entanglement crucial for quantum communication and tests of quantum mechanics.

Contribution

It presents the first experimental realization of atom-photon entanglement with a fidelity of 0.82, advancing quantum information processing capabilities.

Findings

Achieved atom-photon entanglement with 0.82 fidelity.

Verified entanglement through correlation measurements.

Demonstrated potential for loophole-free Bell tests.

Abstract

In 1935 EPR used the assumption of local realism to conclude in a Gedankenexperiment with two entangled particles that quantum mechanics is not complete. Based on this idea Bell constructed an inequality whereby experimental tests could distinguish between quantum mechanics and local-realistic theories. Many experiments have since been done that are consistent with quantum mechanics, disproving the concept of local realism. But all these tests suffered from loopholes allowing a local-realistic explanation of the experimental observations. In this context, of special interest is entanglement between different quantum objects like atoms and photons, because it allows one to entangle distant atoms by the interference of photons. The resulting space-like separation together with the almost perfect detection efficiency of the atoms will allow a first event-ready Bell test closing detection and locality loopholes. The primary goal of the present thesis was the experimental realization of entanglement between a single localized atom and a single spontaneously emitted photon. In the experiment a single optically trapped R87 atom is excited to a state which has two selected decay channels. In the following spontaneous decay a photon is emitted coherently with equal probability into both decay channels. This accounts for perfect correlations between the polarization state of the emitted photon and the Zeeman state of the atom after spontaneous decay. Because these decay channels are spectrally and in all other degrees of freedom indistinguishable, the spin state of the atom is entangled with the polarization state of the photon. To verify entanglement, appropriate correlation measurements in complementary bases of the photon polarization and the internal quantum state of the atom were performed. It is shown, that the generated atom-photon state yields an entanglement fidelity of 0.82.