Molecular states from $\bar{B}N$ interactions

In 2019, two new structures $\Lambda_b(6146)^0$ and $\Lambda_b(6152)^0$ at the invariant mass spectrum of $\Lambda_b^0\pi^{+}\pi^{-}$ observed by the LHCb Collaboration triggers a hot discussion about their inner structure. Although many works study seem to indicate that these two states are conventional three-quark states, $\Lambda_b(6146)^0$ and $\Lambda_b(6152)^0$ might still be $\bar{B}N$ hadronic molecule state, because the mass of $\Lambda_b(6146)^0$ and $\Lambda_b(6152)^0$ are close to the $\bar{B}N$ threshold. In this work, we perform a systematical investigation of the possible heavy molecular states from the interaction of $\bar{B}N$ in a one-boson-exchange approach. The interaction of the system considered is described by the $t$-channel $\sigma$, $\omega$, and $\rho$ mesons exchange. With the one-boson-exchange potentials obtained, the $\bar{B}N$ bound states with different quantum number configurations are got by solving the non-relativistic Schr\"{o}dinger equation. Our calculation suggests that recently observed $\Lambda_b(6146)^0$ can be assigned as a $P$-wave molecular state of $\bar{B}N$ with $I(J^P)=0(3/2^{+})$. However, the $\Lambda_b(6152)^0$ state cannot be accommodated in the current $F$-wave $\bar{B}N$ molecular picture. The calculation also favors the existence of a $S$-wave $\bar{B}N$ state that can not be associated with the $\Lambda_b(5912)^0$. The results in this work are helpful for understanding the high wave molecular states, and future experimental search for the new molecular states.