7Be and 7Li nuclei within the no-core shell model with continuum

Abstract

The production of 7Be and 7Li nuclei plays an important role in primordial nucleosynthesis, nuclear astrophysics, and fusion energy generation. The 3He(α , γ) 7Be and 3H(α , γ) 7Li radiative-capture processes are important to determine the 7Li abundance in the early universe and to predict the correct fraction of pp-chain branches resulting in 7Be versus 8B neutrinos. In this work we study the properties of 7Be and 7Li within the no-core shell model with continuum (NCSMC) method, using chiral nucleon-nucleon interactions as the only input, and analyze all the binary mass partitions involved in the formation of these systems. The NCSMC is an ab initio method applicable to light nuclei that provides a unified description of bound and scattering states and thus is well suited to investigate systems with many resonances and pronounced clustering like 7Be and 7Li. Our calculations reproduce all the experimentally known states of the two systems and provide predictions for several new resonances of both parities. Some of these new possible resonances are built on the ground states of 6Li and 6He, and thus represent a robust prediction. We do not find any resonance in the p+6Li mass partition near the threshold. On the other hand, in the p+6He mass partition of 7Li we observe an S-wave resonance near the threshold producing a very pronounced peak in the calculated S factor of the 6He (p,γ) 7Li radiative-capture reaction, which could be relevant for astrophysics and its implications should be investigated.