Related papers: High-Dimensional Bell States: A Paradigm Shift for Quantum Illumination

High-Dimensional Bell States: A Paradigm Shift for Quantum Illumination

URL: http://arxiv.org/abs/2407.08005v1
Date: Wed, 10 Jul 2024 19:19:31 GMT
Title: High-Dimensional Bell States: A Paradigm Shift for Quantum Illumination
Authors: Armanpreet Pannu, Amr S. Helmy, Hesham El Gamal,
Abstract summary: This paper solves the open problem of characterizing the performance of quantum illumination (QI) with discrete variable states. In the limit as $M rightarrow infty$, the maximally entangled $M$ mode Bell state achieves optimal performance, matching the two-mode squeezed vacuum in a high-noise regime and exceeding it in low-noise. A closer analysis reveals that this advantage stems from retained entanglement in the transmitted Bell state, a paradigm-shifting discovery since interaction with the environment in optical systems is believed to break entanglement.
Score: 1.3654846342364308
License: http://creativecommons.org/licenses/by/4.0/
Abstract: This paper solves the open problem of characterizing the performance of quantum illumination (QI) with discrete variable states. By devising a novel quantum measurement approach along with meticulous analysis, our investigation demonstrates that, in the limit as $M \rightarrow \infty$, the maximally entangled $M$ mode Bell state achieves optimal performance, matching the two-mode squeezed vacuum in a high-noise regime and exceeding it in low-noise. This result challenges the dominance of continuous variable states in photonic sensing applications and extends the novelty of QI to regimes where no quantum advantage was believed to exist. A closer analysis reveals that this advantage stems from retained entanglement in the transmitted Bell state, a paradigm-shifting discovery since interaction with the environment in optical systems is believed to break entanglement. The complete mathematical analysis of this work provides granular insights into the interaction between photonic systems and environmental noise, motivating further research into discrete variable quantum sensing.

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