Charge symmetry breaking in $\Lambda$ hypernuclei revisited
Abstract
The large charge symmetry breaking (CSB) implied by the binding energy difference He)H) = 0.350.06 MeV of the mirror hypernuclei ground states, determined from emulsion studies, has defied theoretical attempts to reproduce it in terms of CSB in hyperon masses and in hyperon-nucleon interactions, including one pion exchange arising from mixing. Using a schematic strong-interaction coupling model developed by Akaishi and collaborators for -shell hypernuclei, we revisit the evaluation of CSB in the hypernuclei and extend it to -shell mirror hypernuclei. The model yields values of MeV. Smaller size and mostly negative -shell binding energy differences are calculated for the mirror hypernuclei, in rough agreement with the few available data. CSB is found to reduce by almost 30 keV the 110 keV B g.s. doublet splitting anticipated from the hyperon-nucleon strong-interaction spin dependence, thereby explaining the persistent experimental failure to observe the -ray transition.
Cite
@article{arxiv.1503.01687,
title = {Charge symmetry breaking in $\Lambda$ hypernuclei revisited},
author = {Avraham Gal},
journal= {arXiv preprint arXiv:1503.01687},
year = {2015}
}
Comments
a few clarifying statements added to v2; matches published PLB version plus a note added after publication on p.13