Consequences of increased hypertriton binding for $s$-shell $\Lambda$-hypernuclear systems
Abstract
Consequences of increasing the binding energy of the hypertriton ground state from the emulsion value =0.130.05 MeV to the STAR value MeV are studied for -shell hypernuclei within a pionless EFT approach at leading order, constrained by the binding energies of the and states. The stochastic variational method is used in bound-state calculations, whereas the inverse analytic continuation in the coupling constant method is used to locate -matrix poles of continuum states. It is found that the resonance becomes broader and less likely to be observed experimentally, whereas the spin-flip virtual state moves closer to the threshold to become a shallow bound state for specific interaction strengths. The effect of such a near-threshold state on femtoscopic studies of -deuteron correlations, and its lifetime if bound, are discussed. Increasing moderately, up to 0.5 MeV, hardly affects calculated values of .
Keywords
Cite
@article{arxiv.2108.13900,
title = {Consequences of increased hypertriton binding for $s$-shell $\Lambda$-hypernuclear systems},
author = {M. Schäfer and B. Bazak and N. Barnea and A. Gal and J. Mareš},
journal= {arXiv preprint arXiv:2108.13900},
year = {2022}
}