English

Deformation and shell effects in nuclear mass formulas

Nuclear Theory 2015-05-30 v1

Abstract

We analyze the ability of the three different Liquid Drop Mass (LDM) formulas to describe nuclear masses for nuclei in various deformation regions. Separating the 2149 measured nuclear species in eight sets with similar quadrupole deformations, we show that the masses of prolate deformed nuclei are better described than those of spherical ones. In fact, the prolate deformed nuclei are fitted with an RMS smaller than 750 keV, while for spherical and semi-magic species the RMS is always larger than 2000 keV. These results are found to be independent of pairing. The macroscopic sector of the Duflo-Zuker (DZ) mass model reproduces shell effects, while most of the deformation dependence is lost and the RMS is larger than in any LDM. Adding to the LDM the microscopically motivated DZ master terms introduces the shell effects, allowing for a significant reduction in the RMS of the fit but still exhibiting a better description of prolate deformed nuclei. The inclusion of shell effects following the Interacting Boson Model's ideas produces similar results.

Keywords

Cite

@article{arxiv.1108.6098,
  title  = {Deformation and shell effects in nuclear mass formulas},
  author = {Cesar Barbero and Jorge G. Hirsch and Alejandro Mariano},
  journal= {arXiv preprint arXiv:1108.6098},
  year   = {2015}
}

Comments

21 pages, 8 figures, 10 tables

R2 v1 2026-06-21T18:57:31.896Z