Revisiting charmless hadronic B decays to scalar mesons

Abstract

Hadronic charmless B decays to scalar mesons are studied within the framework of QCD factorization (QCDF). Considering two different scenarios for scalar mesons above 1 GeV, we find that the data favor the scenario in which the scalars a0(1450) and K0*(1430) are the lowest lying q q bound states. This in turn implies a preferred four-quark nature for light scalars below 1 GeV. Assuming K0*(1430) being a lowest lying q s state, we show that the data of B K0*(1430)η(') and B K0*(1430)(,ω,φ) can be accommodated in QCDF without introducing power corrections induced from penguin annihilation, while the predicted B- K0*0(1430)π- and B0 K0*-(1430)π+ are too small compared to experiment. In principle, the data of K0*(1430)π modes can be explained if penguin-annihilation induced power corrections are taken into account. However, this will destroy the agreement between theory and experiment for B K0*(1430)(η('),,ω,φ). Contrary to the pseudoscalar meson sector where B Kη' has the largest rate in 2-body decays of the B meson, we show that Br(B K0*η')<(B K0*η). The decay B0 a0(980)+K- is found to have a rate much smaller than that of B0 a0(980)+π- in QCDF, while it is the other way around in pQCD. Experimental measurements of these two modes will help discriminate between these two different approaches. Assuming 2-quark bound states for f0(980) and f0(500), the observed large rates of f0(980)K and f0(980)K* modes can be explained in QCDF with the f0(980)\!-\!f0(500) mixing angle θ in the vicinity of 20.