Investigation of neutron density distribution of ²⁰⁸Pb nucleus when the proton density is constrained to its experimental distribution

Abstract: In this study, two novel improvements for the theoretical calculation of neutron distributions are presented. First, the available experimental proton distributions are used as a constraint rather than inferred from the calculation. Second, the recently proposed distribution formula, d3pF, is used for the neutron density, which is more detailed than the usual shapes, for the first time in a nuclear structure calculation. A semi-microscopic approach for binding energy calculation is considered in this study. Ho… Show more

“…The semi-microscopic approaches show remarkable success in the calculation of nuclear masses, deformation [26,[41][42][43][44], and nuclear decays [45][46][47][48]. However, the self-consistent models outperform other models in calculating the distributions of protons and neutrons as the sum of single-particle densities, and this justifies density fluctuation in practical charge distributions that cannot be described by common analytical formulae [49,50].…”

Change in neutron skin thickness after cluster-decay

“…The semi-microscopic approaches show remarkable success in the calculation of nuclear masses, deformation [26,[41][42][43][44], and nuclear decays [45][46][47][48]. However, the self-consistent models outperform other models in calculating the distributions of protons and neutrons as the sum of single-particle densities, and this justifies density fluctuation in practical charge distributions that cannot be described by common analytical formulae [49,50].…”

Change in neutron skin thickness after cluster-decay

Nuclear surface parameters revisited

Taming nucleon density distributions with deep neural network