Machine learning for the prediction of converged energies from ab initio nuclear structure calculations
Marco Knöll, Tobias Wolfgruber, Marc L. Agel, Cedric Wenz, Robert Roth
Abstract
The prediction of nuclear observables beyond the finite model spaces that are accessible through modern ab initio methods, such as the no-core shell model, poses a challenging task in nuclear structure theory. It requires reliable tools for the extrapolation of observables to infinite many-body Hilbert spaces along with reliable uncertainty estimates. In this work we present a universal machine learning tool capable of capturing observable-specific convergence patterns independent of nucleus and interaction. We show that, once trained on few-body systems, artificial neural networks can produce accurate predictions for a broad range of light nuclei. In particular, we discuss neural-network predictions of ground-state energies from no-core shell model calculations for , and based on training data for , and and compare them to classical extrapolations.