Probing Nucleon- cccInteraction via Lattice QCD at Physical Quark Masses

Abstract

We study the S-wave interactions between the nucleon (N) and the triply charmed Omega baryon (ccc) using (2+1)-flavor lattice QCD with a physical pion mass (mπ 137.1 MeV) on a lattice volume (8.1~fm)3. The charm quark is implemented with a relativistic heavy-quark action at its physical mass. Employing the time-dependent HAL QCD method, the N-ccc potentials in the spin-1 (3S1) and spin-2 (5S2) channels are extracted. In both channels, overall attraction is found with the scattering parameters, a0 = 0.56(0.13)(+0.26-0.03) fm and reff = 1.60(0.05)(+0.04-0.12) fm for the 3S1 channel, and a0 = 0.38(0.12)(+0.25-0.00) fm and reff = 2.04(0.10)(+0.03-0.22) fm for the 5S2 channel, indicating the absence of a dibaryon bound state. The extracted potentials are further decomposed into spin-independent and spin-dependent components. The spin-independent potential is a dominant component and features a short-range attractive core and a long-range attractive tail, while the spin-dependent potential shows short-range attraction (repulsion) in the spin-1 (spin-2) channel. Qualitative comparisons with previous studies of the N-J/ and N-sss systems at mπ 146 MeV are provided, emphasizing the role of heavy-hadron chromo-polarizability arising from soft-gluon exchange between the nucleon and flavor-singlet hadrons. The charm quark mass dependence of the N- ccc potential is investigated as well.