English

One-proton emission from the $^6_{\Lambda}$Li hypernucleus

Nuclear Theory 2018-10-31 v1 Nuclear Experiment

Abstract

One-proton (1p) radioactive emission under the influence of the Λ0\Lambda^0-hyperon inclusion is discussed. I investigate the hyper-1p emitter, Λ6^6_{\Lambda}Li, with a time-dependent three-body model. Two-body interactions for α\alpha-proton and α\alpha-Λ0\Lambda^0 subsystems are determined consistently to their resonant and bound energies, respectively. For a proton-Λ0\Lambda^0 subsystem, a contact interaction, which can be linked to the vacuum-scattering length of the proton-Λ0\Lambda^0 scattering, is employed. A noticeable sensitivity of the 1p-emission observables to the scattering length of the proton-Λ0\Lambda^0 interaction is shown. The Λ0\Lambda^0-hyperon inclusion leads to a remarkable fall of the 1p-resonance energy and width from the hyperon-less α\alpha-proton resonance. For some empirical values of the proton-Λ0\Lambda^0 scattering length, the 1p-resonance width is suggested to be of the order of 0.10.010.1-0.01 MeV. Thus, the 1p emission from Λ6^6_{\Lambda}Li may occur in the timescale of 1020102110^{-20}-10^{-21} seconds, which is sufficiently shorter than the self-decay lifetime of Λ0\Lambda^0, 101010^{-10} seconds. By taking the spin-dependence of the proton-Λ0\Lambda^0 interaction into account, a remarkable split of the Jπ=1J^{\pi}=1^- and 22^- 1p-resonance states is predicted. It is also suggested that, if the spin-singlet proton-Λ0\Lambda^0 interaction is sufficiently attractive, the 1p emission from the 11^- ground state is forbidden. From these results, I conclude that the 1p emission can be a suitable phenomenon to investigate the basic properties of the hypernuclear interaction, for which a direct measurement is still difficult.

Keywords

Cite

@article{arxiv.1802.04811,
  title  = {One-proton emission from the $^6_{\Lambda}$Li hypernucleus},
  author = {Tomohiro Oishi},
  journal= {arXiv preprint arXiv:1802.04811},
  year   = {2018}
}

Comments

10 pages, 9 figures, accepted in Phys. Rev. C

R2 v1 2026-06-23T00:21:28.685Z