Quantum entanglement in exactly soluble atomic models: The Moshinsky model with three electrons, and with two electrons in a uniform magnetic field

TL;DR

This paper analytically investigates entanglement in exactly solvable atomic models, specifically a three-electron Moshinsky model and a two-electron model in a magnetic field, revealing how entanglement varies with energy, interaction, and magnetic field strength.

Contribution

It provides the first analytical and exact results on entanglement properties in a three-electron atomic model, exploring dependence on energy, interactions, and magnetic fields.

Findings

Entanglement increases with energy in the three-electron model.

Finite entanglement persists in excited states even with vanishing interaction.

Magnetic field decreases entanglement, approaching a finite value at strong fields.

Abstract

We investigate the entanglement-related features of the eigenstates of two exactly soluble atomic models: a one-dimensional three-electron Moshinsky model, and a three-dimensional two-electron Moshinsky system in an external uniform magnetic field. We analytically compute the amount of entanglement exhibited by the wavefunctions corresponding to the ground, first and second excited states of the three-electron model. We found that the amount of entanglement of the system tends to increase with energy, and in the case of excited states we found a finite amount of entanglement in the limit of vanishing interaction. We also analyze the entanglement properties of the ground and first few excited states of the two-electron Moshinsky model in the presence of a magnetic field. The dependence of the eigenstates' entanglement on the energy, as well as its behaviour in the regime of vanishing interaction, are similar to those observed in the three-electron system. On the other hand, the entanglement exhibits a monotonically decreasing behavior with the strength of the external magnetic field. For strong magnetic fields the entanglement approaches a finite asymptotic value that depends on the interaction strength. For both systems studied here we consider a perturbative approach in order to shed some light on the entanglement's dependence on energy and also to clarify the finite entanglement exhibited by excited states in the limit of weak interactions. As far as we know, this is the first work that provides analytical and exact results for the entanglement properties of a three-electron model.