Spectroscopy of 26F to probe proton-neutron forces close to the drip line

Abstract

A long-lived Jπ=41+ isomer, T1/2=2.2(1)ms, has been discovered at 643.4(1) keV in the weakly-bound 269F nucleus. It was populated at GANIL in the fragmentation of a 36S beam. It decays by an internal transition to the Jπ=11+ ground state (82(14)%), by β-decay to 26Ne, or beta-delayed neutron emission to 25Ne. From the beta-decay studies of the Jπ=11+ and Jπ=41+ states, new excited states have been discovered in 25,26Ne. Gathering the measured binding energies of the Jπ=11+-41+ multiplet in 269F, we find that the proton-neutron π 0d5/2 0d3/2 effective force used in shell-model calculations should be reduced to properly account for the weak binding of 269F. Microscopic coupled cluster theory calculations using interactions derived from chiral effective field theory are in very good agreement with the energy of the low-lying 11+,21+,41+ states in 26F. Including three-body forces and coupling to the continuum effects improve the agreement between experiment and theory as compared to the use of two-body forces only.