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Main Authors: Kopciuch, Marek, Smolis, Magdalena, Miranowicz, Adam, Pustelny, Szymon
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2307.01160
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author Kopciuch, Marek
Smolis, Magdalena
Miranowicz, Adam
Pustelny, Szymon
author_facet Kopciuch, Marek
Smolis, Magdalena
Miranowicz, Adam
Pustelny, Szymon
contents We demonstrate a novel experimental technique for quantum-state tomography of the collective density matrix. It is based on measurements of the polarization of light, traversing the atomic vapor. To assess the technique's robustness against errors, experimental investigations are supported with numerical simulations. This not only allows to determine the fidelity of the reconstruction, but also to analyze the quality of the reconstruction for specific experimental parameters light tuning and number of measurements). By utilizing the so-called conditional number, we demonstrate that the reconstruction can be optimized for a specific tuning of the system parameters, and further improvement is possible by selective repetition of the measurements. Our results underscore the potential high-fidelity quantum-state reconstruction while optimizing measurement resources.
format Preprint
id arxiv_https___arxiv_org_abs_2307_01160
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Optimized experimental optical tomography of quantum states of room-temperature alkali-metal vapor
Kopciuch, Marek
Smolis, Magdalena
Miranowicz, Adam
Pustelny, Szymon
Quantum Physics
Atomic Physics
We demonstrate a novel experimental technique for quantum-state tomography of the collective density matrix. It is based on measurements of the polarization of light, traversing the atomic vapor. To assess the technique's robustness against errors, experimental investigations are supported with numerical simulations. This not only allows to determine the fidelity of the reconstruction, but also to analyze the quality of the reconstruction for specific experimental parameters light tuning and number of measurements). By utilizing the so-called conditional number, we demonstrate that the reconstruction can be optimized for a specific tuning of the system parameters, and further improvement is possible by selective repetition of the measurements. Our results underscore the potential high-fidelity quantum-state reconstruction while optimizing measurement resources.
title Optimized experimental optical tomography of quantum states of room-temperature alkali-metal vapor
topic Quantum Physics
Atomic Physics
url https://arxiv.org/abs/2307.01160