Structures and decay properties of extremely proton-rich nuclei 11,12O

Abstract

Background: The recent observation of the unbound nucleus 11O offers the unique possibility to study how the structure and dynamics of two-proton (2p) decay is affected by the removal of one neutron from 12O, and provides important information on the Thomas-Ehrman effect in the mirror pairs 11~8O3-11~3Li8 and 12~8O4-12~4Be8, which involve the 2p emitters 11O and 12O. Purpose: We investigate how continuum effects impact the structure and decay properties of 11O and 12O, and their mirror partners. Methods: We solve the three-body core-nucleon-nucleon problem using the Gamow coupled-channel (GCC) method. The GCC Hamiltonian employs a realistic finite-range valence nucleon-nucleon interaction and the deformed cores of 9,10C, 9Li, and 10Be. Results: We calculate the energy spectra and decay widths of 11O and 12O as well as those of their mirror nuclei. In particular, we investigate the dynamics of the 2p decay in the ground state of 12O by analyzing the evolution of the 2p configuration of the emitted protons as well as their angular correlations in the coordinate space. We also show how the analytic structure of the resonant states of 10Li and 10N impacts the low-lying states of 11Li and 11O. Conclusions: We demonstrate that, in both nuclei 11O and 12O, there is a competition between direct and "democratic" 2p ground-state emission. The broad structure observed in 11O is consistent with four broad resonances, with the predicted 3/2-1 ground state strongly influenced by the broad threshold resonant state in 10N, which is an isobaric analog of the antibound (or virtual) state in 10Li.