Ab Initio Study of 77Li with Coupled Mass Partitions

Abstract

Background: Lithium is of broad interest in nuclear astrophysics, fusion energy research, and nuclear technology. From a theoretical perspective, the nucleus 7Li presents a remarkable challenge, as its bound and resonant states can exhibit contributions from both the 4He + 3H cluster configuration and configurations involving a neutron or proton coupled to a 6Li or 6He core, respectively. Purpose: We aim to achieve a unified ab initio description of bound-state and continuum properties of 7Li by explicitly including simultaneously the coupled mass/charge partitions 4He + 3H, 6Li + n, and 6He + p. Specifically, we investigate the effect of inter-partition coupling on the spectrum of 7Li and calculate cross sections for the 6Li(n,p)6He, 6He(p,n)6Li, and 6He(p,t)4He reactions. Method: We employ the no-core shell model with continuum for the first time in a calculation that couples three mass/charge partitions of the aggregate nucleus 7Li, using a chiral nucleon-nucleon interaction as input. Results: The calculated spectrum reproduces all the experimentally observed states of 7Li in the correct order and predicts additional resonances. The calculation also reproduces the overall energy dependence of the 6Li(n,p)6He cross section. Improved agreement with measured cross sections is obtained after phenomenological adjustment of resonance energies. Conclusions: The present results show that coupling the relevant mass/charge partitions is important for a consistent description of the 7Li spectrum and reaction cross sections, and offers a useful framework for interpreting existing data and guiding future measurements.