Nuclear rotation in the continuum
Abstract
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. In this work, by studying the collective rotation of the positive-parity deformed configurations of the one-neutron halo nucleus Be, we assess different mechanisms that stabilize collective behavior beyond the limits of particle stability. 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. We demonstrate that collective rotation of the ground band of Be is stabilized by (i) the fact that the one-neutron decay channel is closed, and (ii) the angular momentum alignment, which increases the parentage of high- 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 Be, where the neutron-decay channel is open and often dominates. We demonstrate that long-lived collective states can exist at high excitation energy in weakly bound neutron drip-line nuclei such as Be.
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}
}