Spectroscopy of 35P using the one-proton knockout reaction

Abstract

The structure of 35P was studied with a one-proton knockout reaction at88~MeV/u from a 36S projectile beam at NSCL. The γ rays from thedepopulation of excited states in 35P were detected with GRETINA, whilethe 35P nuclei were identified event-by-event in the focal plane of theS800 spectrograph. The level scheme of 35P was deduced up to 7.5 MeV usingγ-γ coincidences. The observed levels were attributed to protonremovals from the sd-shell and also from the deeply-bound p\1/2 orbital.The orbital angular momentum of each state was derived from the comparisonbetween experimental and calculated shapes of individual (γ-gated)parallel momentum distributions. Despite the use of different reactions andtheir associate models, spectroscopic factors, C2S, derived from the36S (-1p) knockout reaction agree with those obtained earlier from36S(d,3He) transfer, if a reduction factor R\s, as deducedfrom inclusive one-nucleon removal cross sections, is applied to the knockout transitions.In addition to the expected proton-hole configurations, other states were observedwith individual cross sections of the order of 0.5~mb. Based on their shiftedparallel momentum distributions, their decay modes to negative parity states,their high excitation energy (around 4.7~MeV) and the fact that they were notobserved in the (d,3He) reaction, we propose that they may resultfrom a two-step mechanism or a nucleon-exchange reaction with subsequent neutronevaporation. Regardless of the mechanism, that could not yet be clarified, thesestates likely correspond to neutron core excitations in 35P. Thisnewly-identified pathway, although weak, offers the possibility to selectivelypopulate certain intruder configurations that are otherwise hard to produceand identify.