Nuclear structure study using a hybrid approach of shell model and Gogny-type density functionals
Abstract
Nuclear density functional theory (DFT) is able to reproduce the saturation properties of nuclear matter, as well as properties of finite nuclei. Consequently, the DFT calculations are applicable to nuclei across a wide range of masses on nuclear chart. The Gogny-type density functional, which is equivalent to the mean-field calculations with finite-range density-dependent effective interactions, is a successful example. In contrast, the shell-model (configuration-interaction) calculation is a powerful tool to describe nuclear structure, especially spectroscopic properties. The shell model is able to take into account correlations beyond mean field in a truncated model space. In this work, we report investigation on -shell nuclei and Ca isotopes using a hybrid approach of the shell model and Gogny-type DFT.
Cite
@article{arxiv.2505.01072,
title = {Nuclear structure study using a hybrid approach of shell model and Gogny-type density functionals},
author = {Kota Yoshinaga and Noritaka Shimizu and Takashi Nakatsukasa},
journal= {arXiv preprint arXiv:2505.01072},
year = {2025}
}