Predictions of charge density distributions for nuclei with $Z \geq 8$
Provides high-precision charge density data for nuclear physics, atomic physics, and nuclear astrophysics applications.
A deep neural network predicts nuclear charge density distributions for nuclei with Z ≥ 8, achieving root-mean-square deviations of 0.0123 fm and 0.0198 fm for charge radii on training and validation sets, surpassing the precision of the original RCHB calculations.
A deep neural network (DNN) has been developed to accurately predict nuclear charge density distributions for nuclei with proton numbers $Z \geq 8$. By incorporating essential nuclear structure features, the model achieves a significant improvement in predictive accuracy over conventional methods. The charge density distributions are analyzed using a Fourier-Bessel (FB) series expansion, and the DNN is trained on a comprehensive dataset derived from relativistic continuum Hartree-Bogoliubov (RCHB) theory calculations. The model demonstrates exceptional performance, with root-mean-square deviations of 0.0123 fm and 0.0198 fm for charge radii on the training and validation sets, respectively, remarkably surpassing the precision of the original RCHB calculations. Beyond advancing nuclear physics research, this high-precision model provides critical data for applications in atomic physics, nuclear astrophysics, and related fields.