New neutron-rich isotope production in $^{154}$Sm+$^{160}$Gd

TL;DR

This study investigates deep inelastic scattering in $^{154}$Sm+$^{160}$Gd using microscopic models, predicting the production of over 40 new neutron-rich isotopes with potential for novel synthesis methods.

Contribution

First microscopic analysis of $^{154}$Sm+$^{160}$Gd deep inelastic scattering, predicting new neutron-rich isotopes via multi-nucleon transfer.

Findings

No fusion observed due to Coulomb repulsion.

Over 40 new neutron-rich nuclei predicted.

Production cross sections range from microbarns to millibarns.

Abstract

Deep inelastic scattering in $^{154}$Sm+$^{160}$Gd at energies above the Bass barrier is for the first time investigated with two different microscopic dynamics approaches: improved quantum molecular dynamics (ImQMD) model and time dependent Hartree-Fock (TDHF) theory. No fusion is observed from both models. The capture pocket disappears for this reaction due to strong Coulomb repulsion and the contact time of the di-nuclear system formed in head-on collisions is about 700 fm/c at an incident energy of 440 MeV. The isotope distribution of fragments in the deep inelastic scattering process is predicted with the simulations of the latest ImQMD-v2.2 model together with a statistical code (GEMINI) for describing the secondary decay of fragments. More than 40 extremely neutron-rich unmeasured nuclei with $58 \le Z\le 76$ are observed and the production cross sections are at the order of ${\rm \mu b}$ to mb. The multi-nucleon transfer reaction of Sm+Gd could be an alternative way to synthesize new neutron-rich lanthanides which are difficult to be produced with traditional fusion reactions or fission of actinides.