Neutron-rich calcium isotopes within realistic Gamow shell model calculations with continuum coupling

Citations Over TimeTop 10% of 2020 papers

Abstract

Based on the realistic nuclear force of the high-precision CD-Bonn potential, we have performed comprehensive calculations for neutron-rich calcium isotopes using the Gamow shell model (GSM) which includes resonance and continuum. The realistic GSM calculations produce well binding energies, one- and two-neutron separation energies, predicting that $^{57}\mathrm{Ca}$ is the heaviest bound odd isotope and $^{70}\mathrm{Ca}$ is the dripline nucleus. Resonant states are predicted, which provides useful information for future experiments on particle emissions in neutron-rich calcium isotopes. Shell evolutions in the calcium chain around neutron numbers $N=32$, 34, and 40 are understood by calculating effective single-particle energies, the excitation energies of the first ${2}^{+}$ states and two-neutron separation energies. The calculations support shell closures at $^{52}\mathrm{Ca}$ ($N=32$) and $^{54}\mathrm{Ca}$ ($N=34$) but show a weakening of shell closure at $^{60}\mathrm{Ca}$ ($N=40$). The possible shell closure at $^{70}\mathrm{Ca}$ ($N=50$) is predicted.

Related Papers

• → Calculations of the neutron skin and its effect in atomic parity violation(2009)58 cited
• → Shell model calculations in the calcium-isotopes(1966)67 cited
• → Obtaining the Optical Field Isotope Shifts of a Light Element(1971)12 cited
• → Assessment of Stable Isotopes of Calcium for the Measurement of Intestinal Calcium Absorption(1987)1 cited
• Developing a Clinically Useful Calcium Isotope Biomarker(2016)