English

Self-consistent calculations for atomic electron capture

Nuclear Theory 2023-07-26 v2 Atomic Physics

Abstract

We present a comprehensive investigation of electron capture (EC) ratios spanning a broad range of atomic numbers. The study employs a self-consistent computational method that incorporates electron screening, electron correlations, overlap and exchange corrections, as well as shake-up and shake-off atomic effects. The electronic wave functions are computed with the Dirac-Hartree-Fock-Slater (DHFS) method, chosen following a systematic comparison of binding energies, atomic relaxation energies and Coulomb amplitudes against other existing methods and experimental data. A novel feature in the calculations is the use of an energy balance employing atomic masses, which avoids approximating the electron total binding energy and allows a more precise determination of the neutrino energy. This leads to a better agreement of our predictions for capture ratios in comparison with the experimental ones, especially for low-energy transitions. We expand the assessment of EC observables uncertainties by incorporating atomic relaxation energy uncertainties, in contrast to previous studies focusing only on Q-value and nuclear level energies. Detailed results are presented for nuclei of practical interest in both nuclear medicine and exotic physics searches involving liquid Xenon detectors (67Ga^{67}\mathrm{Ga}, 111In^{111}\mathrm{In}, 123I^{123}\mathrm{I}, 125I^{125}\mathrm{I} and 125Xe^{125}\mathrm{Xe}). Our study can be relevant for astrophysical, nuclear, and medical applications.

Keywords

Cite

@article{arxiv.2304.10373,
  title  = {Self-consistent calculations for atomic electron capture},
  author = {V. A. Sevestrean and O. Niţescu and S. Ghinescu and S. Stoica},
  journal= {arXiv preprint arXiv:2304.10373},
  year   = {2023}
}

Comments

16 pages, 9 figures, 4 tables

R2 v1 2026-06-28T10:12:34.911Z