Negativity percolation in continuous-variable quantum networks

IF 8.3 1区物理与天体物理 Q1 PHYSICS, APPLIED

npj Quantum Information Pub Date : 2026-03-14 DOI:10.1038/s41534-026-01210-5

Yaqi Zhao, Kan He, Yongtao Zhang, Jinchuan Hou, Jianxi Gao, Shlomo Havlin, Xiangyi Meng

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引用次数: 0

Abstract

Quantum networks (QNs) have been predominantly driven by discrete-variable (DV) architectures. Yet, optical platforms naturally generate Gaussian states—the common states of continuous-variable (CV) systems, making CV-based QNs an attractive route toward scalable, chip-integrated quantum computation and communication. To bridge the gap between well-studied DV entanglement percolation theories and their CV counterpart, we introduce a Gaussian-to-Gaussian entanglement distribution scheme that deterministically transports two-mode squeezed vacuum states across large CV networks. Analysis of the scheme’s collective behavior using statistical-physics methods reveals a new form of entanglement percolation—negativity percolation theory (NegPT)—characterized by a bounded entanglement measure called the ratio negativity. We discover that NegPT exhibits a mixed-order phase transition, marked simultaneously by both an abrupt change in global entanglement and a long-range correlation between nodes. This distinctive behavior places CV-based QNs in a new universality class, fundamentally distinct from DV systems. Additionally, the abruptness of this transition introduces a critical vulnerability of CV-based QNs: conventional feedback mechanism becomes inherently unstable near the threshold, highlighting practical implications for stabilizing large-scale CV-based QNs. Our results unify statistical models for CV-based entanglement distribution and uncover previously unexplored critical phenomena unique to CV systems, providing valuable insights and guidelines essential for developing robust, feedback-stabilized QNs.

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连续变量量子网络中的负性渗透

量子网络（QNs）主要由离散变量（DV）架构驱动。然而，光学平台自然会产生高斯态——连续变量（CV）系统的共同状态，这使得基于CV的量子网络成为可扩展的、芯片集成的量子计算和通信的有吸引力的途径。为了弥补已经得到充分研究的DV纠缠渗透理论和CV纠缠渗透理论之间的差距，我们引入了一种高斯到高斯纠缠分布方案，该方案在大型CV网络中确定性地传输双模压缩真空态。利用统计物理方法对方案的集体行为进行分析，揭示了纠缠渗透的一种新形式——负性渗透理论（NegPT）——以一种称为负比的有界纠缠度量为特征。我们发现，NegPT表现出一种混合阶相变，同时表现为全局纠缠的突变和节点之间的远程相关性。这种独特的行为将基于cv的qn置于一个新的通用性类中，从根本上与DV系统不同。此外，这种转变的突兀性引入了基于cv的qn的一个关键漏洞：传统的反馈机制在阈值附近变得固有不稳定，突出了稳定大规模基于cv的qn的实际意义。我们的研究结果统一了基于CV的纠缠分布的统计模型，并揭示了CV系统以前未被探索的独特关键现象，为开发鲁棒的反馈稳定qn提供了有价值的见解和指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

npj Quantum Information Computer Science-Computer Science (miscellaneous)

CiteScore

13.70

自引率

3.90%

发文量

130

审稿时长

29 weeks

期刊介绍： The scope of npj Quantum Information spans across all relevant disciplines, fields, approaches and levels and so considers outstanding work ranging from fundamental research to applications and technologies.