Ab initio benchmarks of neutrinoless double beta decay in light nuclei with a chiral Hamiltonian

Abstract

We report ab initio benchmark calculations of nuclear matrix elements (NMEs) for neutrinoless double-beta (0ββ) decays in light nuclei with mass number ranging from A=6 to A=22. We use the transition operator derived from light-Majorana neutrino exchange and evaluate the NME with three different methods: two variants of in-medium similarity renormalization group (IMSRG) and importance-truncated no-core shell model (IT-NCSM). The same two-plus-three-nucleon interaction from chiral effective field theory is employed, and both isospin-conserving ( T=0) and isospin-changing ( T=2) transitions are studied. We compare our resulting ground-state energies and NMEs to those of recent ab initio no-core shell model and coupled-cluster calculations, also with the same inputs. We show that the NMEs of T=0 transitions are in good agreement among all calculations, at the level of 10%. For T=2, relative deviations are more significant in some nuclei. The comparison with the exact IT-NCSM result allows us to analyze these cases in detail, and indicates the next steps towards improving the IMSRG-based approaches. The present study clearly demonstrates the power of consistent cross-checks that are made possible by ab initio methodology. This capability is crucial for providing meaningful many-body uncertainties in the NMEs for the 0ββ decays in heavier candidate nuclei, where quasi-exact benchmarks are not available.