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Autori principali: Chen, Yinan, Elben, Andreas, Rubio, Angel, Refael, Gil
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.11158
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author Chen, Yinan
Elben, Andreas
Rubio, Angel
Refael, Gil
author_facet Chen, Yinan
Elben, Andreas
Rubio, Angel
Refael, Gil
contents Quantum-enhanced sensors, which surpass the standard quantum limit (SQL) and approach the fundamental precision limits dictated by quantum mechanics, are finding applications across a wide range of scientific fields. This quantum advantage becomes particularly significant when a large number of particles are included in the sensing circuit. Achieving such enhancement requires introducing and preserving entanglement among many particles, posing significant experimental challenges. In this work, we integrate concepts from Floquet theory and quantum information to design an entangler capable of generating the desired entanglement between two paths of a quantum interferometer. We demonstrate that our path-entangled states enable sensing beyond the SQL, reaching the fundamental Heisenberg limit (HL) of quantum mechanics. Moreover, we show that a decoding parity measurement maintains the HL when specific conditions from Floquet theory are satisfied$\unicode{x2013}$particularly those related to the periodic driving parameters that preserve entanglement during evolution. We address the effects of a priori phase uncertainty and imperfect transmission, showing that our method remains robust under realistic conditions. Finally, we propose a superconducting-circuit implementation of our sensor in the microwave regime, highlighting its potential for practical applications in high-precision measurements.
format Preprint
id arxiv_https___arxiv_org_abs_2410_11158
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Bosonic Entanglement and Quantum Sensing from Energy Transfer in two-tone Floquet Systems
Chen, Yinan
Elben, Andreas
Rubio, Angel
Refael, Gil
Quantum Physics
Mesoscale and Nanoscale Physics
Quantum-enhanced sensors, which surpass the standard quantum limit (SQL) and approach the fundamental precision limits dictated by quantum mechanics, are finding applications across a wide range of scientific fields. This quantum advantage becomes particularly significant when a large number of particles are included in the sensing circuit. Achieving such enhancement requires introducing and preserving entanglement among many particles, posing significant experimental challenges. In this work, we integrate concepts from Floquet theory and quantum information to design an entangler capable of generating the desired entanglement between two paths of a quantum interferometer. We demonstrate that our path-entangled states enable sensing beyond the SQL, reaching the fundamental Heisenberg limit (HL) of quantum mechanics. Moreover, we show that a decoding parity measurement maintains the HL when specific conditions from Floquet theory are satisfied$\unicode{x2013}$particularly those related to the periodic driving parameters that preserve entanglement during evolution. We address the effects of a priori phase uncertainty and imperfect transmission, showing that our method remains robust under realistic conditions. Finally, we propose a superconducting-circuit implementation of our sensor in the microwave regime, highlighting its potential for practical applications in high-precision measurements.
title Bosonic Entanglement and Quantum Sensing from Energy Transfer in two-tone Floquet Systems
topic Quantum Physics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2410.11158