Nuclear Field Theory predictions for 11Li and 12Be: shedding light on the origin of pairing in nuclei

TL;DR

This paper uses Nuclear Field Theory to analyze two-neutron transfer reactions in 11Li and 12Be, highlighting phonon-mediated pairing as key to halo neutron binding and exploring medium polarization effects on nuclear pairing.

Contribution

It provides a unified theoretical framework predicting the role of collective vibrations and halo properties in neutron pairing in light nuclei, with specific reaction cross section calculations.

Findings

Phonon-mediated pairing dominates neutron halo binding in 11Li.

Existence of a pairing vibrational band based on 9Li.

Predicted reaction cross sections are sensitive to halo orbital treatment.

Abstract

Recent data resulting from studies of two-nucleon transfer reaction on 11Li, analyzed through a unified nuclear-structure-direct-reaction theory have provided strong direct as well as indirect confirmation, through the population of the first excited state of 9Li and of the observation of a strongly quenched ground state transition, of the prediction that phonon mediated pairing interaction is the main mechanism binding the neutron halo of the 8.5 ms-lived 11Li nucleus. In other words, the ground state of 11Li can be viewed as a neutron Cooper pair bound to the 9Li core, mainly through the exchange of collective vibration of the core and of the pigmy resonance arizing from the sloshing back and forth of the neutron halo against the protons of the core, the mean field leading to unbound two particle states, a situation essentially not altered by the bare nucleon-nucleon interaction acting between the halo neutrons. Two-neutron pick-up data, together with (t,p) data on 7Li, suggest the existence of a pairing vibrational band based on 9Li, whose members can be excited with the help of inverse kinematic experiments as was done in the case of 11Li(p,t)9Li reaction. The deviation from harmonicity can provide insight into the workings of medium polarization effects on Cooper pair nuclear pairing, let alone specific information concering the "rigidity" of the N=6 shell closure. Further information concerning these questions is provided by the predicted absolute differential cross sections associated with the reactions 12Be(p,t)10Be(gs) and 12Be(p,t)10Be(pv)(~10Be(p,t)8Be(gs)). In particular, concerning this last reaction, predictions of \sigma_{abs} can change by an order of magnitude depending on whether the halo properties associated with the d_{5/2} orbital are treated selfconsistently in calculating the ground state correlations of the (pair removal) mode, or not.