Search for excited states in 25O

Abstract

Theoretical calculations suggest the presence of low-lying excited states in 25O. Previous experimental searches by means of proton knockout on 26F produced no evidence for such excitations. We search for excited states in 25O using the 24O (d,p) 25O reaction. The theoretical analysis of excited states in unbound 25,27O is based on the configuration interaction approach that accounts for couplings to the scattering continuum. We use invariant-mass spectroscopy to measure neutron-unbound states in 25O. For the theoretical approach, we use the complex-energy Gamow Shell Model and Density Matrix Renormalization Group method with a finite-range two-body interaction optimized to the bound states and resonances of 23-26O, assuming a core of 22O. We predict energies, decay widths, and asymptotic normalization coefficients. Our calculations in a large spdf space predict several low-lying excited states in 25O of positive and negative parity, and we obtain an experimental limit on the relative cross section of a possible Jπ = 1/2+ state with respect to the ground-state of 25O at σ1/2+/σg.s. = 0.25-0.25+1.0. We also discuss how the observation of negative parity states in 25O could guide the search for the low-lying negative parity states in 27O. Previous experiments based on the proton knockout of 26F suffered from the low cross sections for the population of excited states in 25O because of low spectroscopic factors. In this respect, neutron transfer reactions carry more promise.