English

Nuclear rotation in the continuum

Nuclear Theory 2016-02-24 v2

Abstract

Background:{\textbf{Background:}} Atomic nuclei often exhibit collective rotational-like behavior in highly excited states, well above the particle emission threshold. What determines the existence of collective motion in the continuum region, is not fully understood. Purpose:{\textbf{Purpose:}} In this work, by studying the collective rotation of the positive-parity deformed configurations of the one-neutron halo nucleus 11^{11}Be, we assess different mechanisms that stabilize collective behavior beyond the limits of particle stability. Method:{\textbf{Method:}} To solve a particle-plus-core problem, we employ a non-adiabatic coupled-channel formalism and the Berggren single-particle ensemble, which explicitly contains bound states, narrow resonances, and the scattering continuum. We study the valence-neutron density in the intrinsic rotor frame to assess the validity of the adiabatic approach as the excitation energy increases. Results:{\textbf{Results:}} We demonstrate that collective rotation of the ground band of 11^{11}Be is stabilized by (i) the fact that the =0\ell=0 one-neutron decay channel is closed, and (ii) the angular momentum alignment, which increases the parentage of high-\ell components at high spins; both effects act in concert to decrease decay widths of ground-state band members. This is not the case for higher-lying states of 11^{11}Be, where the =0\ell=0 neutron-decay channel is open and often dominates. Conclusion:{\textbf{Conclusion:}} We demonstrate that long-lived collective states can exist at high excitation energy in weakly bound neutron drip-line nuclei such as 11^{11}Be.

Keywords

Cite

@article{arxiv.1509.07841,
  title  = {Nuclear rotation in the continuum},
  author = {K. Fossez and W. Nazarewicz and Y. Jaganathen and N. Michel and M. Płoszajczak},
  journal= {arXiv preprint arXiv:1509.07841},
  year   = {2016}
}
R2 v1 2026-06-22T11:05:46.681Z