Properties of a trapped multiple-species bosonic mixture at the infinite-particle-number limit: A solvable model.

IF 3.1 2区 化学 Q3 CHEMISTRY, PHYSICAL Journal of Chemical Physics Pub Date : 2024-11-14 DOI:10.1063/5.0238967
O E Alon, L S Cederbaum
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Abstract

We investigate a trapped mixture of Bose-Einstein condensates consisting of a multiple number of P species. To be able to do so, an exactly solvable many-body model is called into play. This is the P-species harmonic-interaction model. After presenting the Hamiltonian, the ground-state energy and wavefunction are explicitly calculated. All properties of the mixture's ground state can, in principle, be obtained from the many-particle wavefunction. A scheme to integrate the all-particle density matrix is derived and implemented, leading to closed-form expressions for the reduced one-particle density matrices. Of particular interest is the infinite-particle-number limit, which is obtained when the numbers of bosons are taken to infinity while keeping the interaction parameters fixed. We first prove that at the infinite-particle-number limit all the species are 100% condensed. The mean-field solution of the P-species mixture is also obtained analytically and is used to show that the energy per particle and densities per particle computed at the many-body level of theory boil down to their mean-field counterparts. Despite these, correlations in the mixture exist at the infinite-particle-number limit. To this end, we obtain closed-form expressions for the correlation energy, namely, the difference between the mean-field and many-body energies, and the depletion of the species, i.e., the number of particles residing outside the condensed modes, at the infinite-particle-number limit. The depletion and the correlation energy per species are shown to critically depend on the number of species. Of separate interest is the entanglement between one species of bosons and the other P - 1 species. This quantity is governed by the coupling of the center-of-mass coordinates of the species and is obtained by the respective Schmidt decomposition of the P-species wavefunction. Interestingly, there is an optimal number of species, here P = 3, where the entanglement is maximal. Importantly, the manifestation of this interspecies entanglement in an observable is possible. It is the position-momentum uncertainty product of one species in the presence of the other P - 1 species, which is derived and demonstrated to correlate with the interspecies entanglement. All in all, we show and explain how correlations at the infinite-particle-number limit of a trapped multiple-species bosonic mixture depend on the interactions and how they evolve with the number of species. Generalizations and implications are briefly discussed.

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无限粒子数极限下被困多物种玻色混合物的特性:一个可解模型。
我们研究了一种由多种 P 物质组成的玻色-爱因斯坦凝聚体的被困混合物。为了做到这一点,我们需要一个可精确求解的多体模型。这就是 P 物种谐波相互作用模型。在提出哈密顿方程后,基态能量和波函数将被明确计算出来。原则上,混合物基态的所有性质都可以从多粒子波函数中获得。我们推导并实施了一种对全粒子密度矩阵进行积分的方案,从而得到了单粒子密度矩阵的封闭式表达式。我们特别关注的是无穷粒子数极限,即在保持相互作用参数固定的情况下,玻色子的数量达到无穷大时得到的极限。我们首先证明,在无限粒子数极限,所有物种都是 100% 凝聚的。我们还通过分析得到了 P 粒子混合物的均场解,并用它来证明在多体理论水平上计算出的每个粒子的能量和密度可以归结为其均场对应值。尽管如此,混合物中的相关性仍然存在于无限粒子数极限。为此,我们得到了相关能(即均场能与多体能之差)和物种耗竭(即在无限粒子数极限下,存在于凝聚模式之外的粒子数)的闭合表达式。结果表明,每个物种的耗竭和相关能与物种数量密切相关。另一个值得关注的问题是一种玻色子与其他 P - 1 物种之间的纠缠。这个量受制于物种质量中心坐标的耦合,并由 P-物种波函数的各自施密特分解得到。有趣的是,存在一个最佳的物种数量,这里是 P = 3,在这个数量上,纠缠是最大的。重要的是,这种物种间的纠缠有可能在观测数据中体现出来。这是一个物种在其他 P - 1 个物种存在时的位置-动量不确定性乘积,它被推导并证明与物种间的纠缠相关。总之,我们展示并解释了被困多物种玻色混合物在无限粒子数极限时的相关性如何取决于相互作用,以及它们如何随物种数量而演变。此外,我们还简要讨论了其普遍性和影响。
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
Journal of Chemical Physics
Journal of Chemical Physics 物理-物理:原子、分子和化学物理
CiteScore
7.40
自引率
15.90%
发文量
1615
审稿时长
2 months
期刊介绍: The Journal of Chemical Physics publishes quantitative and rigorous science of long-lasting value in methods and applications of chemical physics. The Journal also publishes brief Communications of significant new findings, Perspectives on the latest advances in the field, and Special Topic issues. The Journal focuses on innovative research in experimental and theoretical areas of chemical physics, including spectroscopy, dynamics, kinetics, statistical mechanics, and quantum mechanics. In addition, topical areas such as polymers, soft matter, materials, surfaces/interfaces, and systems of biological relevance are of increasing importance. Topical coverage includes: Theoretical Methods and Algorithms Advanced Experimental Techniques Atoms, Molecules, and Clusters Liquids, Glasses, and Crystals Surfaces, Interfaces, and Materials Polymers and Soft Matter Biological Molecules and Networks.
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