Unified description of 6Li structure and deuterium-4He dynamics with chiral two- and three-nucleon forces

Abstract

Prototype for the study of weakly bound projectiles colliding on stable targets, the scattering of deuterium (d) on 4He (α) is an important milestone in the search for a fundamental understanding of low-energy reactions. At the same time, it is also important for its role in the Big-bang nucleosynthesis of 6Li and applications in the characterization of deuterium impurities in materials. We present the first unified ab initio study of the 6Li ground state and d-4He elastic scattering using two- and three-nucleon forces derived within the framework of chiral effective field theory. The six-nucleon bound-state and scattering observables are calculated by means of the no-core shell model with continuum. %and are compared to available experimental data. We analyze the influence of the dynamic polarization of the deuterium and of the chiral three-nucleon force, and examine the role of the continuum degrees of freedom in shaping the low-lying spectrum of 6Li. We find that the adopted Hamiltonian correctly predicts the binding energy of 6Li, yielding an asymptotic D- to S-state ratio of the 6Li wave function in d+α configuration of -0.027 in agreement with the value determined from a phase shift analysis of 6Li+4He elastic scattering, but overestimates the excitation energy of the first 3+ state by 350 keV. The bulk of the computed differential cross section is in good agreement with data.