Many-Body Dynamics in Monitored Atomic Gases without Postselection Barrier

Gianluca Passarelli; Xhek Turkeshi; Angelo Russomanno; Procolo Lucignano; Marco Schirò; Rosario Fazio

doi:10.1103/PhysRevLett.132.163401

Many-Body Dynamics in Monitored Atomic Gases without Postselection Barrier

Gianluca Passarelli
, Xhek Turkeshi
, Angelo Russomanno
, Procolo Lucignano
, Marco Schirò
, Rosario Fazio

C/o Complesso di Monte S. Angelo
University of Naples Federico II
Collège de France
Abdus Salam International Centre for Theoretical Physics

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We study the properties of a monitored ensemble of atoms driven by a laser field and in the presence of collective decay. The properties of the quantum trajectories describing the atomic cloud drastically depend on the monitoring protocol and are distinct from those of the average density matrix. By varying the strength of the external drive, a measurement-induced phase transition occurs separating two phases with entanglement entropy scaling subextensively with the system size. Incidentally, the critical point coincides with the superradiance transition of the trajectory-averaged dynamics. Our setup is implementable in current light-matter interaction devices, and most notably, the monitored dynamics is free from the postselection measurement problem, even in the case of imperfect monitoring.

langue originale	Anglais
Numéro d'article	163401
journal	Physical Review Letters
Volume	132
Numéro de publication	16
Les DOIs	https://doi.org/10.1103/PhysRevLett.132.163401
état	Publié - 19 avr. 2024
Modification externe	Oui

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10.1103/PhysRevLett.132.163401

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abstract = "We study the properties of a monitored ensemble of atoms driven by a laser field and in the presence of collective decay. The properties of the quantum trajectories describing the atomic cloud drastically depend on the monitoring protocol and are distinct from those of the average density matrix. By varying the strength of the external drive, a measurement-induced phase transition occurs separating two phases with entanglement entropy scaling subextensively with the system size. Incidentally, the critical point coincides with the superradiance transition of the trajectory-averaged dynamics. Our setup is implementable in current light-matter interaction devices, and most notably, the monitored dynamics is free from the postselection measurement problem, even in the case of imperfect monitoring.",

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AU - Passarelli, Gianluca

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AU - Russomanno, Angelo

AU - Lucignano, Procolo

AU - Schirò, Marco

AU - Fazio, Rosario

PY - 2024/4/19

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AB - We study the properties of a monitored ensemble of atoms driven by a laser field and in the presence of collective decay. The properties of the quantum trajectories describing the atomic cloud drastically depend on the monitoring protocol and are distinct from those of the average density matrix. By varying the strength of the external drive, a measurement-induced phase transition occurs separating two phases with entanglement entropy scaling subextensively with the system size. Incidentally, the critical point coincides with the superradiance transition of the trajectory-averaged dynamics. Our setup is implementable in current light-matter interaction devices, and most notably, the monitored dynamics is free from the postselection measurement problem, even in the case of imperfect monitoring.

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Many-Body Dynamics in Monitored Atomic Gases without Postselection Barrier

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