Lattice QCD studies on decuplet baryons as meson-baryon bound states in the HAL QCD method

Abstract

We study decuplet baryons from meson-baryon interactions in lattice QCD, in particular, and baryons from P-wave I=3/2 Nπ and I=0 K interactions, respectively. Interaction potentials are calculated in the HAL QCD method using 3-quark-type source operators at mπ ≈ 410~MeV and mK ≈ 635~MeV, where as well as baryons are stable. We use the conventional stochastic estimate of all-to-all propagators combined with the all-mode averaging to reduce statistical fluctuations. We have found that the K system has a weaker attraction than the Nπ system while the binding energy from the threshold is larger for than . This suggests that an inequality mN+mπ-m<m+m K-m comes mainly from a smaller spatial size of a K bound state due to a larger reduced mass, rather than its interaction. Root-mean-square distances of bound states in both systems are small, indicating that and are tightly bound states and thus can be regarded qualitatively as composite states of 3 quarks. Results of binding energies agree with those obtained from temporal 2-point functions within large systematic errors, which arise dominantly from the lattice artifact at short distances.