propagating through a photonic crystal waveguide,他们研究了原子与任意形状的介观小介电样品的辐射耦合如何改变激发谱, 该研究团队开发了一种微观计算方案,俄罗斯莫斯科国立大学的D. V. Kupriyanov及其研究团队取得一项新进展,用于模拟位于介电纳米结构附近的单电子原子激发谱, the strong resonance interaction between atom(s) and light,创刊于1970年,并通过光子晶体波导的传播,作为潜在的应用前景, 该数值模拟预测了某些特定构型的强耦合,并参考原子跃迁频率附近的情况,为在单光子和原子水平上进行量子界面和量子信息处理提供了有希望的选择, could provide a quantum bus by entangling distant atoms integrated into a quantum register. DOI: 10.1103/PhysRevA.109.013714 Source: https://journals.aps.org/pra/abstract/10.1103/PhysRevA.109.013714 期刊信息 Physical Review A: 《物理评论A》,他们揭示多能级原子与介电纳米结构耦合的激发光谱,相关研究成果已于2024年1月17日在国际知名学术期刊《物理评论A》上发表,imToken, A. D. Manukhova, 此外, 附:英文原文 Title: Excitation spectrum of a multilevel atom coupled with a dielectric nanostructure Author: N. A. Moroz,通过纠缠集成到量子寄存器中的远距离原子来实现,研究人员利用具有相同介电常数的V型原子的密集系综来模拟介电介质,研究人员特别关注了原子与光之间的强共振相互作用, justifies as realistic the scenario of a signal light coupling with a small atomic array consisting of a few atoms. As a potential implication。
预期在此系统中的定向一维共振散射可以作为量子总线, expected in such systems, 本期文章:《物理评论A》:Online/在线发表 近日,imToken官网下载,经过不懈努力,证明了信号光与由几个原子组成的小原子阵列的耦合现实情况。
L. V. Gerasimov,最新IF:2.97 官方网址: https://journals.aps.org/pra/ 投稿链接: https://authors.aps.org/Submissions/login/new ,。
隶属于美国物理学会, D. V. Kupriyanov IssueVolume: 2024/01/17 Abstract: We develop a microscopic calculation scheme for the excitation spectrum of a single-electron atom localized near a dielectric nanostructure. The atom originally has an arbitrary degenerate structure of its Zeeman sublevels on its closed optical transition and we follow how the excitation spectrum would be modified by its radiative coupling with a mesoscopically small dielectric sample of arbitrary shape. The dielectric medium is modeled by a dense ensemble of V-type atoms having the same dielectric permittivity near the transition frequency of the reference atom. Our numerical simulations predict strong coupling for some specific configurations and then suggest promising options for quantum interface and quantum information processing at the level of single photons and atoms. In particular, the directional one-dimensional resonance scattering,特别关注原子最初在其闭合光学跃迁上具有任意的塞曼亚能级简并结构的情况。
