Entanglement with Negative Wigner Function of Three Thousand Atoms Heralded by One Photon

TL;DR

This paper reports the creation of a large-scale entangled atomic ensemble with a negative Wigner function, heralded by a single photon, demonstrating nonclassicality and near-complete entanglement of thousands of atoms.

Contribution

It is the first demonstration of a negative Wigner function and near-entanglement of almost all atoms in a large ensemble using heralded photon detection.

Findings

Reconstructed a negative-valued Wigner function in a large atomic ensemble.

Verified an entanglement depth of approximately 2910 atoms.

Achieved a state with almost all atoms mutually entangled.

Abstract

Quantum-mechanically correlated (entangled) states of many particles are of interest in quantum information, quantum computing and quantum metrology. Metrologically useful entangled states of large atomic ensembles have been experimentally realized, but these states display Gaussian spin distribution functions with a non-negative Wigner function. Non-Gaussian entangled states have been produced in small ensembles of ions, and very recently in large atomic ensembles. Here, we generate entanglement in a large atomic ensemble via the interaction with a very weak laser pulse; remarkably, the detection of a single photon prepares several thousand atoms in an entangled state. We reconstruct a negative-valued Wigner function, an important hallmark of nonclassicality, and verify an entanglement depth (minimum number of mutually entangled atoms) of 2910(190) out of 3100 atoms. This is the first time a negative Wigner function or the mutual entanglement of virtually all atoms have been attained in an ensemble containing more than a few particles. While the achieved purity of the state is slightly below the threshold for entanglement-induced metrological gain, further technical improvement should allow the generation of states that surpass this threshold, and of more complex Schrodinger cat states for quantum metrology and information processing. More generally, our results demonstrate the power of heralded methods for entanglement generation, and illustrate how the information contained in a single photon can drastically alter the quantum state of a large system.