Structure of14B and the evolution ofN=9single-neutron isotones

Abstract

We have used the ${}^{13}$B($d,p$)${}^{14}$B reaction in inverse kinematics to study the properties of states in ${}^{14}$B, the lightest particle-bound $N=9$ isotone. The spectroscopic information, including spins, parities, and spectroscopic factors for the states observed in ${}^{14}$B are used to deduce the wave functions for the low-lying negative parity $\ensuremath{\nu}(\mathit{sd})$ levels, as well as provide information about the evolution of the effective neutron $1{s}_{1/2}\ensuremath{-}0{d}_{5/2}$ single-particle energies. The data confirm that the ground and first-excited states are predominantly $s$ wave in character and are single-neutron halo states. The effective single-particle energies are found to match the trends set by other $N=9$ isotones.