原子耗散影响下通过两个遥远的原子腔系统增强量子资源

IF 2.4 3区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Communications in Theoretical Physics Pub Date : 2024-01-02 DOI:10.1088/1572-9494/ad19d5

M. Setodeh Kheirabady, M. Tavassoly, Mehran Rafeie, E. Ghasemian

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引用次数: 0

摘要

纠缠和相干等量子资源是现代量子技术的圣杯。尽管量子信息处理任务会受到不必要的环境影响，但{color{blue}令人兴奋的是}这些关键量子资源可以通过一些特殊的混合开放量子系统得到保护甚至增强。{color{blue}在此，我们旨在展示如何通过耗散原子腔系统来生成增强的量子资源。｝为此，我们考虑了几个耗散空腔，每个空腔包含两个有效的两级原子，它们与单模空腔场相互作用。{在实际应用中，可以使用经典激光场来驱动每个原子子系统。驱动系统后，对系统输出进行贝尔态测量（BSM），以量化纠缠和相干性。}研究结果表明，即使在耗散作用下，存在于两个遥远空腔内的原子之间的远距离纠缠和相干性不仅增强了，而且可以稳定下来。相反，由于存在不必要的环境效应，每个耗散腔内两个原子之间的局部纠缠会减弱。尽管如此，局部相干可能会表现出与远程相干相同的行为。{color{blue}此外，该系统还能在各种相互作用情况下提供稳态纠缠，尤其是在原子-空腔强耦合和相对较大的失谐情况下。更有趣的是，我们的数值分析表明，由于在相互作用过程中发生了纠缠的消亡和恢复，该系统可能显示出记忆效应。｝我们提出的模型有可能应用于长距离量子网络的实现。特别是，它有助于在大规模量子网络的节点之间分配量子资源，实现安全通信。\\

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Enhanced quantum resources via two distant atom-cavity systems under the influence of atomic dissipation

Quantum resources such as entanglement and coherence are the holy grail for modern quantum technologies. Although the unwanted environmental effects tackle quantum information processing tasks, {\color{blue}suprisingly} these key quantum resources may be protected and even enhanced by the implementation of some special hybrid open quantum systems. {\color{blue} Here, we aim to show that how a dissipative atom-cavity-system can be accomplished to generate enhanced quantum resources.} To do so, we consider a couple of dissipative cavities, where each one contains two effective two-level atoms interacting with a single-mode cavity field. {\color{blue} In practical applications, a classical laser field may be applied to drive each atomic subsystem. After driving the system, a Bell-state measurement (BSM) is performed on the output of the system to quantify the entanglement and coherence. } The obtained results reveal that the remote entanglement and coherence between the atoms existing inside the two distant cavities not only enhanced, but can be stabilized, even under the action of dissipation. In contrast, the local entanglement between two atoms inside each dissipative cavity attenuates due to the presence of unwanted environmental effects. Nevertheless, the local coherence may show the same behavior as the remote coherence. {\color{blue} Besides, the system provides the steady state entanglement in various interaction regimes, particularly in the strong atom-cavity coupling and with the relatively large detuning. More interestingly, our numerical analyses demonstrate that the system may show memory effect due top the fact that the death and revival of entanglement take place during the interaction.} Our proposed model may find potential applications for the implementation of long distance quantum networks. In particular, it facilitates the distribution of quantum resources between the nodes of large-scale quantum networks for secure communication. \\

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来源期刊

Communications in Theoretical Physics 物理-物理：综合

CiteScore

5.20

自引率

3.20%

发文量

6110

审稿时长

4.2 months

期刊介绍： Communications in Theoretical Physics is devoted to reporting important new developments in the area of theoretical physics. Papers cover the fields of: mathematical physics quantum physics and quantum information particle physics and quantum field theory nuclear physics gravitation theory, astrophysics and cosmology atomic, molecular, optics (AMO) and plasma physics, chemical physics statistical physics, soft matter and biophysics condensed matter theory others Certain new interdisciplinary subjects are also incorporated.