Radiative and Semileptonic B Decays Involving Higher K-Resonances in the Final States

Abstract

We study the radiative and semileptonic B decays involving a spin-J resonant KJ(*) with parity (-1)J for KJ* and (-1)J+1 for KJ in the final state. Using the large energy effective theory (LEET) techniques, we formulate B KJ(*) transition form factors in the large recoil region in terms of two independent LEET functions ζKJ(*) and ζKJ(*), the values of which at zero momentum transfer are estimated in the BSW model. According to the QCD counting rules, ζ,KJ(*) exhibit a dipole dependence in q2. We predict the decay rates for B KJ(*) γ, B KJ(*) + - and B KJ(*) . The branching fractions for these decays with higher K-resonances in the final state are suppressed due to the smaller phase spaces and the smaller values of ζKJ(*),. Furthermore, if the spin of KJ(*) becomes larger, the branching fractions will be further suppressed due to the smaller Clebsch-Gordan coefficients defined by the polarization tensors of the KJ(*). We also calculate the forward backward asymmetry of the B KJ(*) + - decay, for which the zero is highly insensitive to the K-resonances in the LEET parametrization.