Deep learning on nuclear mass and α decay half-lives

Abstract

Ab-initio calculations of nuclear masses, the binding energy and the α decay half-lives are intractable for heavy nucleus, because of the curse of dimensionality in many body quantum simulations as proton number(N) and neutron number(Z) grow. We take advantage of the powerful non-linear transformation and feature representation ability of deep neural network(DNN) to predict the nuclear masses and α decay half-lives. For nuclear binding energy prediction problem we achieve standard deviation σ=0.263 MeV on 10-fold cross validation on 2149 nuclei. Word-vectors which are high dimensional representation of nuclei from the hidden layers of mass-regression DNN help us to calculate α decay half-lives. For this task, we get σ=0.797 on 100 times 10-fold cross validation on 350 nuclei on log10T1/2 and σ=0.731 on 486 nuclei. We also find physical a priori such as shell structure, magic numbers and augmented inputs inspired by Finite Range Droplet Model are important for this small data regression task.