Litcius/Paper detail

Ultrafast preparation and detection of entangled atoms

S. Eckart, D. Trabert, J. Rist, A. Geyer, Lothar Schmidt, K. Fehre, M. Kunitski

2023Science Advances12 citationsDOIOpen Access PDF

Abstract

Atoms can form a molecule by sharing their electrons in binding orbitals. These electrons are entangled. Is there a way to break a molecular bond and obtain atoms in their ground state that are spatially separated and still entangled? Here, we show that it is possible to prepare these spatially separated, entangled atoms on femtosecond time scales from single oxygen molecules. The two neutral atoms are entangled in the magnetic quantum number of their valence electrons. In a time-delayed probe step, we use nonadiabatic tunneling, which is a magnetic quantum number-sensitive ionization mechanism. We find a fingerprint of entanglement in the measured ionization probability as a function of the angle between the light's quantization axis and the molecular axis. This establishes a platform for further experiments that harness the time resolution of strong-field experiments to investigate spatially separated, entangled atoms on femtosecond time scales.

Topics & Concepts

ElectronQuantum entanglementIonizationPhysicsFemtosecondAtomic physicsValence electronAtomic orbitalAtoms in moleculesAtom (system on chip)QuantumMolecular physicsLaserQuantum mechanicsIonComputer scienceEmbedded systemQuantum Information and CryptographyLaser-Matter Interactions and ApplicationsCold Atom Physics and Bose-Einstein Condensates
Ultrafast preparation and detection of entangled atoms | Litcius