光晶格中极性分子链的量子纠缠

doi:10.3969/j.issn.1000-5641.2023.04.008

摘要/Abstract

摘要：

极性分子受到外电场作用, 其分子轴将绕电场方向在一定范围内振荡, 形成摆动态. 通过选择能级最低的磁量子数 $ M = 0 $ 的两个摆动态作为量子比特, 研究了囚禁在一维光晶格中的分子链的量子纠缠. 计算了共生纠缠度、全局纠缠度与和电场强度、永久偶极矩、转动常数、偶极–偶极相互作用及温度等有关的3个无量纲变量之间的关系, 从而阐明了极性分子链的量子纠缠的特点.

关键词: 量子纠缠, 极性分子, 摆动态, 光晶格

Abstract:

For a polar molecule subjected to an external electric field, its molecular axis will oscillate around the direction of the electric field, forming pendular states. Taking the two lowest-lying pendular states with magnetic quantum number $M=0 $ as qubit states, we study quantum entanglement of polar molecular arrays trapped in a one-dimensional optical lattice. We evaluate pairwise concurrence and global entanglement as functions of three dimensionless variables related to external field intensity–permanent dipole moment, a rotation constant, dipole-dipole interaction, and temperature —thus revealing the properties of the entangled molecular dipole arrays.

Key words: quantum entanglement, polar molecule, pendular state, optical lattice

中图分类号:

O413

岳文静, 魏启. 光晶格中极性分子链的量子纠缠[J]. 华东师范大学学报（自然科学版）, 2023, 2023(4): 74-85.

Wenjing YUE, Qi WEI. Quantum entanglement of molecular dipole arrays trapped in an optical lattice[J]. Journal of East China Normal University(Natural Science), 2023, 2023(4): 74-85.

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