Entanglement entropy and Schmidt number as measures of delocalization of $\alpha$ clusters in one-dimensional nuclear systems

TL;DR

This paper investigates entanglement measures like von Neumann entropy and Schmidt number to quantify cluster delocalization in 1D nuclear systems, revealing their effectiveness and differences in various delocalization states.

Contribution

It introduces a comparative analysis of entanglement measures in 1D cluster states and proposes a new generalized entanglement measure for delocalization.

Findings

Schmidt number closely matches von Neumann entropy in fully delocalized states.

Schmidt number is less sensitive to partial delocalization than von Neumann entropy.

A new generalized entanglement measure is proposed for better sensitivity.

Abstract

We calculated the von Neumann entanglement entropy and the Schmidt number of one dimentional (1D) cluster states and showed that these are useful measures to estimate entanglement caused by delocalization of clusters. We analyze system size dependence of these entanglement measures in the linear-chain $n\alpha$ states given by Tohsaki-Horiuchi-Schuck-R\"opke wave functions for 1D cluster gas states. We show that the Schmidt number is an almost equivalent measures to the von Neumann entanglement entropy when the delocalization of clusters occurs in the entire system but it shows different behaviors in a partially delocalized state containing localized clusters and delocalized ones. It means that the R\'enyi-2 entanglement entropy, which relates to the Schmidt number, is found to be almost equivalent to the von Neumann entanglement entropy for the full delocalized cluster system but it is less sensitive to the partially delocalized cluster system than the von Neumann entanglement entropy. We also propose a new entanglement measure which has a generalized form of the Schmidt number. Sensitivity of these measures of entanglement to the delocalization of clusters in low-density regions was discussed.