Separation energies of light hypernuclei and their theoretical uncertainties

Abstract

Separation energies of light hypernuclei (A≤ 5) and their theoretical uncertainties are investigated. Few-body calculations are performed within the Faddeev-Yakubovsky scheme and the no-core shell model. Thereby, modern and up-to-date N\!N and Y\!N potentials derived within chiral effective field theory are employed. % It is found that the numerical uncertainties of the few-body methods are well under control and an accuracy of around 1 keV for the hypertriton and of less than 20 keV for the separation energies of the 4He and 5He hypernuclei can be achieved. Variations caused by differences in the N\!N interaction are in the order of 10 keV for 3H and no more than 110 keV for A=4,\,5 hypernuclei, when recent high-precision potentials up to fifth order in the chiral expansion are employed. The variations are smaller than expected contributions from chiral Y\!N\!N three-body forces (3BFs) which arise at the chiral order of state-of-the-art Y\!N potentials. Estimates for those 3BFs are deduced from a study of the truncation uncertainties in the chiral expansion.