Hadronic Molecular States Composed of Heavy Flavor Baryons

Abstract

We investigate the possible molecules composed of two heavy flavor baryons such as "AQBQ"(Q=b, c) within the one-pion-exchange model (OPE). Our results indicate that the long-range π exchange force is strong enough to form molecules such as [QQ']I=1/2S=1(Q=b, c), [QQ]I=1S=1(Q=b, c), [bb']I=3/2S=1 and [b'b]I=0S=1 where the S-D mixing plays an important role. In contrast, the π exchange does not form the spin-singlet AQBQ bound states. If we consider the heavier scalar and vector meson exchanges as well as the pion exchange, some loosely bound spin-singlet S-wave states appear while results of the spin-triplet AQBQ system does not change significantly, which implies the pion exchange plays an dominant role in forming the spin-triplet molecules. Moreover, we perform an extensive coupled channel analysis of the QQ system within the OPE and one-boson-exchange (OBE) framework and find that there exist loosely bound states of QQ(Q=b,c) with quantum numbers I(JP)=0(0+), 0(0-) and 0(1-). The binding solutions of QQ system mainly come from the coupled-channel effect in the flavor space. Besides the OPE force, the medium- and short-range attractive force also plays a significant role in the formation of the loosely bound cc and bb states. Once produced, they will be very stable because such a system decays via weak interaction with a very long lifetime around 10-1310-12s.