# Single-particle structure of the N = 20 and N = 28 isotones within the   dispersive optical model

**Authors:** O.V. Bespalova, A.A. Klimochkina

arXiv: 1812.00845 · 2019-02-27

## TL;DR

This study uses the dispersive optical model to analyze neutron single-particle structures in N=20 and 28 isotones, showing good agreement with experimental data and demonstrating the model's predictive power for neutron-rich nuclei.

## Contribution

It applies a global dispersive optical model with specific parameters to predict neutron single-particle structures near the neutron drip line, including nuclei with large neutron excess.

## Key findings

- Reduction of particle-hole energy gaps observed.
- Degeneration of 1f7/2 and 2p states confirmed.
- Rapid reduction of 2p-splitting compared to 1f-splitting.

## Abstract

The neutron single-particle characteristics of the N = 20, 28 isotones at 8 < Z < 30 was calculated within the dispersive optical model. The global parameters of the spin-orbit and imaginary parts of the potential as well as surface absorption independent on neutron-proton asymmetry and increased diffuseness at large neutron excess were used in the calculations. The suitability of the global parameters to predict the evolution of the neutron single-particle structure of nuclei near the neutron drip line was investigated. The following results are in agreement with the available experimental data: the reduction of the particle-hole energy gaps, the degeneration of the 1f7/2 and 2p states and then a change in the 1f7/2 , 2p3/2 level sequence and more rapid reduction of the 2p-splitting in comparison with the 1f-splitting with decreasing Z. The predictive power of the dispersive optical model with respect to neutron-rich nuclei is demonstrated.

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Source: https://tomesphere.com/paper/1812.00845