Uncertainty quantification for $\mu \to e$ conversion in nuclei: charge distributions
Abstract
Predicting the rate for conversion in nuclei for a given set of effective operators mediating the violation of lepton flavor symmetry crucially depends on hadronic and nuclear matrix elements. In particular, the uncertainties inherent in this non-perturbative input limit the discriminating power that can be achieved among operators by studying different target isotopes. In order to quantify the associated uncertainties, as a first step, we go back to nuclear charge densities and propagate the uncertainties from electron scattering data for a range of isotopes relevant for conversion in nuclei, including Ca, Ti, and Al. We provide as central results Fourier-Bessel expansions of the corresponding charge distributions with complete covariance matrices, accounting for Coulomb-distortion effects in a self-consistent manner throughout the calculation. As an application, we evaluate the overlap integrals for conversion mediated by dipole operators. In combination with modern ab-initio methods, our results will allow for the evaluation of general conversion rates with quantified uncertainties.
Keywords
Cite
@article{arxiv.2406.06677,
title = {Uncertainty quantification for $\mu \to e$ conversion in nuclei: charge distributions},
author = {Frederic Noël and Martin Hoferichter},
journal= {arXiv preprint arXiv:2406.06677},
year = {2024}
}
Comments
63 pages, 17 figures, python notebook with charge distributions included as supplementary material; journal version