Nucleon-nucleon correlations in the extreme oxygen isotopes

TL;DR

This paper investigates nucleon-nucleon correlations in extreme oxygen isotopes using a novel time-dependent three-body approach, revealing how decay dynamics and correlations are influenced by nuclear structure and continuum effects.

Contribution

It introduces a new framework to study decay dynamics and correlations in exotic oxygen isotopes, connecting wave function components with experimental observations.

Findings

Diproton and cigarlike structures influence decay correlations.

Decay of $^{26}$O aligns with universal phase-space limit.

Continuum effects significantly impact wave functions and decay behavior.

Abstract

There has been an upsurge of interest in two-nucleon decays thanks to the studies of nucleon-nucleon correlations. In our previous work, based on a novel time-dependent three-body approach, we demonstrated that the energy and angular correlations of the emitted nucleons can shed light on the structure of nucleonic pairs formed inside the nucleus. In this work, we apply the new framework to study the decay dynamics and properties of some extreme proton-rich and neutron-rich oxygen isotopes, including two-proton ($2p$) decays of $^{11,12}$O and two-neutron ($2n$) decay of $^{26}$O. Here we show that the low-$\ell$ components of $^{11,12}$O wave functions, which are affected by continuum and configuration-interaction effects, strongly impact decay dynamics and asymptotic correlations. In the calculated wave functions of $^{11,12}$O, diproton and cigarlike structures merge together during the tunneling process and the resulting energy- and angular correlations are very consistent with the experimental data. The asymptotic correlations of the $2n$ decay of $^{26}$O dramatically change as the two-neutron decay energy approaches the zero-energy threshold. The small reported value of $Q_{2n}$ suggests that the $2n$ decay of this nucleus can be understood in terms of the universal phase-space limit.