Predictions for charmed nuclei based on Yc N forces inferred from lattice QCD simulations

Abstract

Charmed nuclei are investigated utilizing c N and c N interactions that have been extrapolated from lattice QCD simulations at unphysical masses of mπ = 410--570 MeV to the physical point using chiral effective field theory as guideline. Calculations of the energies of c single-particle bound states for various charmed nuclei from \ 5_cLi to 209_cBi are performed using a perturbative many-body approach. This approach allows one to determine the finite nuclei c self-energy from which the energies of the different bound states can be obtained. Though the c N interaction inferred from the lattice results is only moderately attractive, it supports the existence of charmed nuclei. Already the lightest nucleus considered is found to be bound. The spin-orbit splitting of the p- and d-wave states turns out to be small, as in the case of single hypernuclei. Additional calculations based on the Faddeev-Yakubovsky equations suggest that also A=4 systems involving a c baryon are likely to be bound, but exclude a bound \, 3_cHe state.