English

Rotational bands beyond the Elliott model

Nuclear Theory 2021-07-07 v1 Nuclear Experiment

Abstract

Rotational bands are commonplace in the spectra of atomic nuclei. Inspired by early descriptions of these bands by quadrupole deformations of a liquid drop, Elliott constructed a discrete nucleon representations of SU(3)\mathrm{SU}(3) from fermionic creation and annihilation operators. Ever since, Elliott's model has been foundational to descriptions of rotation in nuclei. Later work, however, suggested the symplectic extension Sp(3,R)\mathrm{Sp}(3,R) provides a more unified picture. We decompose no-core shell-model nuclear wave functions into symmetry-defined subspaces for several beryllium isotopes, as well as 20^{20}Ne, using the quadratic Casimirs of both Elliott's SU(3)\mathrm{SU}(3) and Sp(3,R)\mathrm{Sp}(3,R). The band structure, delineated by strong B(E2)B(E2) values, has a more consistent description in Sp(3,R)\mathrm{Sp}(3,R) rather than SU(3)\mathrm{SU}(3). {In particular, we confirm previous work finding in some nuclides strongly connected upper and lower bands with the same underlying symplectic structure.

Keywords

Cite

@article{arxiv.2011.08307,
  title  = {Rotational bands beyond the Elliott model},
  author = {Ryan Zbikowski and Calvin W. Johnson and Anna E. McCoy and Mark A. Caprio and Patrick J. Fasano},
  journal= {arXiv preprint arXiv:2011.08307},
  year   = {2021}
}

Comments

30 pages, 15 figures

R2 v1 2026-06-23T20:17:58.795Z