Generation of highly retrievable atom photon entanglement with a millisecond lifetime via a spatially multiplexed cavity

TL;DR

This paper reports a method to generate highly retrievable, long-lived atom-photon entanglement using a polarization interferometer cavity, achieving a 540 microsecond storage time and improved retrieval efficiency for quantum communication.

Contribution

The authors demonstrate a novel cavity setup with dual modes that enables perfect qubit retrieval and significantly extends entanglement storage time compared to previous methods.

Findings

Achieved 540 microsecond storage time for atom-photon entanglement.

Realized 50% intrinsic qubit retrieval efficiency.

Extended entanglement lifetime by 13.5 times over previous records.

Abstract

Qubit memory that is entangled with photonic qubit is the building block for long distance quantum repeaters. Cavity enhanced and long lived spin wave photon entanglement has been demonstrated by applying dual laser beams onto optical-lattice atoms. However, owing to cross readouts by two beams, retrieval efficiency of spin wave qubit is decreased by one quarter compared to that of single mode spin wave at all storage times. Here, by coupling cold atoms to two modes of a polarization interferometer based cavity, we achieve perfect qubit retrieval in cavity enhanced and long lived atom photon entanglement. A write laser beam is applied onto cold atoms, we then create a magnetic field insensitive spin wave qubit that is entangled with the photonic qubit encoded onto two arms of the interferometer. The spin wave qubit is retrieved by a read beam, which avoids the cross readouts. Our experiment demonstrates 540{\mu}s storage time at 50% intrinsic qubit retrieval efficiency, which is 13.5 times longer than the best reported result.