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Autori principali: Tang, Ziqian, Xue, Hanyu, Han, Zizhao, Kan, Zikuan, Li, Zeji, Liu, Yulong
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2411.12631
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author Tang, Ziqian
Xue, Hanyu
Han, Zizhao
Kan, Zikuan
Li, Zeji
Liu, Yulong
author_facet Tang, Ziqian
Xue, Hanyu
Han, Zizhao
Kan, Zikuan
Li, Zeji
Liu, Yulong
contents The interface between quantum mechanics and gravity remains an unresolved issue. Recent advances in precision measurement suggest that detecting gravity-induced entanglement in oscillator systems could provide key evidence for the quantum nature of gravity. However, thermal decoherence imposes strict constraints on system parameters. For entanglement to occur, mechanical frequency $ω_m$, dissipation rate $γ_m$, environmental temperature $T$, oscillator density $ρ$, and the form factor $Λ$-determined by the geometry and arrangement of oscillators-must satisfy a specific constraint. This constraint, intrinsic to the noise model, is considered universal and cannot be improved by quantum control. Given the difficulty in further optimizing $ω_m$, $γ_m$, $ρ$, and $T$, optimizing $Λ$ can relax the constraints on these parameters. In this work, we prove that the form factor has a supremum of $2π$, revealing a fundamental limit of the oscillator system. We propose designs that approach this supremum, nearly an order of magnitude higher than typical spherical oscillators. This optimization could ease experimental constraints and bring quantum gravity validation based on gravity-induced entanglement closer to realization.
format Preprint
id arxiv_https___arxiv_org_abs_2411_12631
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimal Form Factors for Experimental Proposals on Gravity-Induced Entanglement
Tang, Ziqian
Xue, Hanyu
Han, Zizhao
Kan, Zikuan
Li, Zeji
Liu, Yulong
Quantum Physics
The interface between quantum mechanics and gravity remains an unresolved issue. Recent advances in precision measurement suggest that detecting gravity-induced entanglement in oscillator systems could provide key evidence for the quantum nature of gravity. However, thermal decoherence imposes strict constraints on system parameters. For entanglement to occur, mechanical frequency $ω_m$, dissipation rate $γ_m$, environmental temperature $T$, oscillator density $ρ$, and the form factor $Λ$-determined by the geometry and arrangement of oscillators-must satisfy a specific constraint. This constraint, intrinsic to the noise model, is considered universal and cannot be improved by quantum control. Given the difficulty in further optimizing $ω_m$, $γ_m$, $ρ$, and $T$, optimizing $Λ$ can relax the constraints on these parameters. In this work, we prove that the form factor has a supremum of $2π$, revealing a fundamental limit of the oscillator system. We propose designs that approach this supremum, nearly an order of magnitude higher than typical spherical oscillators. This optimization could ease experimental constraints and bring quantum gravity validation based on gravity-induced entanglement closer to realization.
title Optimal Form Factors for Experimental Proposals on Gravity-Induced Entanglement
topic Quantum Physics
url https://arxiv.org/abs/2411.12631