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Autori principali: McCord, John J., Dogra, Shruti, Paraoanu, Gheorghe Sorin
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2307.05214
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author McCord, John J.
Dogra, Shruti
Paraoanu, Gheorghe Sorin
author_facet McCord, John J.
Dogra, Shruti
Paraoanu, Gheorghe Sorin
contents Quantum physics allows an object to be detected even in the absence of photon absorption by the use of so-called interaction-free measurements. We provide a formulation of this protocol using a three-level system, where the object to be detected is a pulse coupled resonantly to the second transition. In the original formulation of interaction-free measurements, the absorption is associated with a projection operator onto the third state. We perform an in-depth analytical and numerical analysis of the coherent protocol, where coherent interaction between the object and the detector replaces the projective operators, resulting in higher detection efficiencies. We provide approximate asymptotic analytical results to support this finding. We find that our protocol reaches the Heisenberg limit when evaluating the Fisher information at small strengths of the pulses we aim to detect -- in contrast to the projective protocol that can only reach the standard quantum limit. We also demonstrate that the coherent protocol remains remarkably robust under errors such as pulse-rotation phases and strengths, the effects of relaxation rates and detunings, as well as different thermalized initial states.
format Preprint
id arxiv_https___arxiv_org_abs_2307_05214
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Theory of coherent interaction-free detection of pulses
McCord, John J.
Dogra, Shruti
Paraoanu, Gheorghe Sorin
Quantum Physics
Quantum physics allows an object to be detected even in the absence of photon absorption by the use of so-called interaction-free measurements. We provide a formulation of this protocol using a three-level system, where the object to be detected is a pulse coupled resonantly to the second transition. In the original formulation of interaction-free measurements, the absorption is associated with a projection operator onto the third state. We perform an in-depth analytical and numerical analysis of the coherent protocol, where coherent interaction between the object and the detector replaces the projective operators, resulting in higher detection efficiencies. We provide approximate asymptotic analytical results to support this finding. We find that our protocol reaches the Heisenberg limit when evaluating the Fisher information at small strengths of the pulses we aim to detect -- in contrast to the projective protocol that can only reach the standard quantum limit. We also demonstrate that the coherent protocol remains remarkably robust under errors such as pulse-rotation phases and strengths, the effects of relaxation rates and detunings, as well as different thermalized initial states.
title Theory of coherent interaction-free detection of pulses
topic Quantum Physics
url https://arxiv.org/abs/2307.05214