Machine learning the deuteron
Abstract
We use machine learning techniques to solve the nuclear two-body bound state problem, the deuteron. We use a minimal one-layer, feed-forward neural network to represent the deuteron S- and D-state wavefunction in momentum space, and solve the problem variationally using ready-made machine learning tools. We benchmark our results with exact diagonalisation solutions. We find that a network with 6 hidden nodes (or 24 parameters) can provide a faithful representation of the ground state wavefunction, with a binding energy that is within 0.1% of exact results. This exploratory proof-of-principle simulation may provide insight for future potential solutions of the nuclear many-body problem using variational artificial neural network techniques.
Cite
@article{arxiv.1911.13092,
title = {Machine learning the deuteron},
author = {J. W. T. Keeble and A. Rios},
journal= {arXiv preprint arXiv:1911.13092},
year = {2020}
}
Comments
8 pages, 7 figures - Final published version including extended analysis and appendices