Gamow shell model description of the radiative capture reaction $^8$Li$(n,\gamma)$$^9$Li

TL;DR

This paper employs the Gamow shell model in coupled-channel form to theoretically study the $^8$Li$(n, extgamma)$ reaction, providing insights into its properties and reaction rate relevant for nucleosynthesis, where experimental data are scarce.

Contribution

The study introduces a GSM-CC approach to accurately model the $^8$Li$(n, extgamma)$ reaction and reproduces experimental spectra and reaction rates, offering a new theoretical perspective.

Findings

GSM-CC reproduces low-energy spectra and reaction thresholds.

Calculated reaction rate aligns with experimental upper limits.

Direct E1 transition dominates the reaction cross section.

Abstract

The $^8$Li$(n,\gamma)$$^9$Li reaction plays a critical role in several reaction chains leading to the nucleosynthesis of $A>12$ nuclei. Due to unstable nature of $^8$Li and the unavailability of neutron targets, direct measurements of this reaction are exceedingly difficult. Only upper limits of this cross section, provided by the indirect experiments, have been obtained so far. In this work, we use the Gamow shell model (GSM) in the coupled-channel representation (GSM-CC) to study the properties of $^9$Li and the radiative capture reaction $^8$Li$(n,\gamma)$$^9$Li. In GSM-CC calculations, a translationally invariant Hamiltonian is used with a finite-range two-body interaction tuned to reproduce the low-energy spectra of $^{8-9}$Li. In the calculation of $^8$Li$(n,\gamma)$$^9$Li cross section, all relevant E1, M1, and E2 transitions from the initial continuum states to the final bound states ${3/2}_1^-$, ${1/2}_1^-$ and the resonance ${5/2}_1^-$ of $^9$Li are included. The GSM-CC approach reproduces the experimental low-energy spectrum, neutron emission threshold, and spectroscopic factors in $^9$Li. The calculated reaction rate is consistent with the experimental upper limit of the reaction rate obtained in the indirect measurements at stellar energies. The GSM-CC calculations suggest that the $^8$Li$(n,\gamma)$$^9$Li reaction can reduce heavy-element production via the main chain $^7$Li($n,\gamma$)$^8$Li($\alpha,n$)$^{11}$B($n,\gamma$)$^{12}$B($\beta^+$)$^{12}$C. Major contribution to the calculated cross section is given by the direct E1 transition to the ground state of $^8$Li. The contribution of excited states to the reaction rate does not exceed $\sim$18% of the total reaction rate.