Finite-Width Effects in Three-Body B Decays

Abstract

It is customary to apply the so-called narrow width approximation (B RP3 P1P2P3)=(B RP3)Br(R P1P2) to extract the branching fraction of the quasi-two-body decay B RP3, with R and P3 being an intermediate resonant state and a pseudoscalar meson, respectively. However, the above factorization is valid only in the zero width limit. We consider a correction parameter ηR from finite width effects. Our main results are: (i) We present a general framework for computing ηR and show that it can be expressed in terms of the normalized differential rate and determined by its value at the resonance. (ii) We introduce a form factor F(s12,mR) for the strong coupling involved in the R(m12) P1P2 decay when m12 is away from mR. We find that off-shell effects are small in vector meson productions, but prominent in the K2*(1430), σ/f0(500) and K0*(1430) resonances. (iii) We evaluate ηR in the theoretical framework of QCD factorization (QCDF) and in the experimental parameterization (EXPP) for three-body decay amplitudes. In general, ηR QCDF and ηR EXPP are similar for vector mesons, but different for tensor and scalar resonances. A study of the differential rates enables us to understand the origin of their differences. (iv) Finite-width corrections to Br(B- RP) NWA obtained in the narrow width approximation are generally small, less than 10\%, but they are prominent in B-σ/f0(500)π- and B- K0*0(1430)π- decays. The EXPP of the normalized differential rates should be contrasted with the theoretical predictions from QCDF calculation as the latter properly takes into account the energy dependence in weak decay amplitudes.