Matrix-product state approach to the generalized nuclear pairing Hamiltonian

Abstract

We show that from the point of view of the generalized pairing Hamiltonian, the atomic nucleus is a system with small entanglement and can thus be described efficiently using a 1D tensor network (matrix-product state) despite the presence of long-range interactions. The ground state can be obtained using the density-matrix renormalization group (DMRG) algorithm, which is accurate up to machine precision even for large nuclei, is numerically as cheap as the widely used BCS (Bardeen-Cooper-Schrieffer) approach, and does not suffer from any mean-field artifacts. We apply this framework to compute the even-odd mass differences of all known lead isotopes from 178Pb to 220Pb in a very large configuration space of 13 shells between the neutron magic numbers 82 and 184 (i.e., two major shells) and find good agreement with the experiment. We also treat pairing with non-zero angular momentum and determine the lowest excited states in the full configuration space of one major shell, which we demonstrate for the N=126, Z≥ 82 isotones. To demonstrate the capabilities of the method beyond low-lying excitations, we calculate the first 100 excited states of 208Pb with singlet pairing and the two-neutron removal spectral function of 210Pb, which relates to a two-neutron pickup experiment.