and ηb mass shifts in nuclear matter

Abstract

We estimate the , ηb and B* meson mass shifts in symmetric nuclear matter. The interest is, whether the strengths of the bottomonium-(nuclear matter) and charmonium-(nuclear matter) interactions are similar or different. This is because, each (J/,) and (ηc,ηb) meson group is usually assumed to have very similar properties based on the heavy charm and bottom quark masses. The estimate for the is made using an SU(5) effective Lagrangian and the anomalous coupling one, by studying the BB, BB*, and B*B* meson loop contributions for the self-energy. As for the ηb, we include the BB* and B*B* meson loop contributions in the self-energy. The in-medium masses of the B and B* mesons appearing in the self-energy are calculated by the quark-meson coupling model. An analysis on the BB, BB*, and B*B* meson loops in the mass shift is made by comparing with the corresponding DD, DD*, and D*D* meson loops for the J/ mass shift. Our prediction for the ηb mass shift is made including only the lowest order BB* meson loop. The mass shift, with including only the BB loop, is predicted to be -16 to -22 MeV at the nuclear matter saturation density using the BB coupling constant determined by the vector meson dominance model with the experimental data, while the ηb mass shift is predicted to be -75 to -82 MeV with the SU(5) universal coupling constant determined by the BB coupling constant. Our results show an appreciable difference between the bottomonium-(nuclear matter) and charmonium-(nuclear matter) interaction strengths. We also study the and ηb mass shifts in a heavy quark (heavy meson) symmetry limit.