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Localized $N, Λ, Σ$, and $Ξ$ Single-Particle Potentials in Finite Nuclei Calculated with $SU_6$ Quark-Model Baryon-Baryon Interactions

arXiv:0904.0517 · doi:10.1103/PhysRevC.79.054318

Abstract

Localized single-particle potentials for all octet baryons, $N$, $Λ$, $Σ$, and $Ξ$, in finite nuclei, $^{12}$C, $^{16}$O, $^{28}$Si, $^{40}$Ca, $^{56}$Fe, and $^{90}$Zr, are calculated using the quark-model baryon-baryon interactions. $G$-matrices evaluated in symmetric nuclear matter in the lowest order Brueckner theory are applied to finite nuclei in local density approximation. Non-local potentials are localized by a zero-momentum Wigner transformation. Empirical single-particle properties of the nucleon and the $Λ$ hyperon in nuclear medium have been known to be explained semi-quantitatively in the LOBT framework. Attention is focused in the present consideration on predictions for the $Σ$ and $Ξ$ hyperons. The unified description for the octet baryon-baryon interactions by the SU$_6$ quark-model enables us to obtain less ambiguous extrapolation to the $S=-1$ and $S=-2$ sectors based on the knowledge in the $NN$ sector than other potential models. The $Σ$ mean field is shown to be weakly attractive at the surface, but turns to be repulsive inside, which is consistent with the experimental evidence. The $Ξ$ hyperon s.p. potential is also attractive at the nuclear surface region, and inside fluctuates around zero. Hence $Ξ$ hypernuclear bound states are unlikely. We also evaluate energy shifts of the $Σ^-$ and $Ξ^-$ atomic levels in $^{28}$Si and $^{56}$Fe, using the calculated s.p. potentials.