Saved in:
Bibliographic Details
Main Authors: Tang, Ziqian, Han, Zizhao, Kan, Zikuan, Yang, Chen, Li, Zeji, Jiang, Yining, Liu, Yulong
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.08869
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914160987602944
author Tang, Ziqian
Han, Zizhao
Kan, Zikuan
Yang, Chen
Li, Zeji
Jiang, Yining
Liu, Yulong
author_facet Tang, Ziqian
Han, Zizhao
Kan, Zikuan
Yang, Chen
Li, Zeji
Jiang, Yining
Liu, Yulong
contents Massive quantum systems have emerged as compelling tabletop interface-systems for testing the quantum nature of gravity. However, conventional schemes that focus on directly using gravity to induce entanglement suffer from overwhelming environmental decoherence: maintaining entanglement between two oscillators requires an impractically high mechanical quality factor. In this work, we put forward an alternative reservoir-engineered scheme, whose core function is to quantify how gravity modifies (rather than prepares) the steady-state entanglement. Compared to quantum gravity, classical gravity introduces additional dissipative channels, which in turn give rise to distinct entanglement characteristics and thus enable the discrimination between the two types of gravity. Notably, this entanglement difference can still be maintained even when the mechanical quality factor is far below the threshold required by conventional schemes. Moreover, it demonstrates significant robustness against non-gravitational couplings, specifically, those like Casimir and Coulomb forces that are inherent in experimental setups. Our scheme relaxes the experimental requirements for verifying quantum gravity, thereby paving a new path toward its near-term realization.
format Preprint
id arxiv_https___arxiv_org_abs_2511_08869
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum-classical gravity distinction in reservoir-engineered massive quantum system
Tang, Ziqian
Han, Zizhao
Kan, Zikuan
Yang, Chen
Li, Zeji
Jiang, Yining
Liu, Yulong
Quantum Physics
Massive quantum systems have emerged as compelling tabletop interface-systems for testing the quantum nature of gravity. However, conventional schemes that focus on directly using gravity to induce entanglement suffer from overwhelming environmental decoherence: maintaining entanglement between two oscillators requires an impractically high mechanical quality factor. In this work, we put forward an alternative reservoir-engineered scheme, whose core function is to quantify how gravity modifies (rather than prepares) the steady-state entanglement. Compared to quantum gravity, classical gravity introduces additional dissipative channels, which in turn give rise to distinct entanglement characteristics and thus enable the discrimination between the two types of gravity. Notably, this entanglement difference can still be maintained even when the mechanical quality factor is far below the threshold required by conventional schemes. Moreover, it demonstrates significant robustness against non-gravitational couplings, specifically, those like Casimir and Coulomb forces that are inherent in experimental setups. Our scheme relaxes the experimental requirements for verifying quantum gravity, thereby paving a new path toward its near-term realization.
title Quantum-classical gravity distinction in reservoir-engineered massive quantum system
topic Quantum Physics
url https://arxiv.org/abs/2511.08869