Charged charmonium-like Z+(4430) from rescattering in conventional B decays

Abstract

In a previous paper we suggested an explanation for the peak designated as Z(4430)+ in the π+ mass spectrum, observed by Belle in \!B π+ K decays, as an effect of \!D\,*0D\,+ π+ rescattering in the decays \!B Ds\, - D, where the Ds\, - is an as-yet unobserved radial excitation of the pseudoscalar ground state Ds\,--meson. In this paper, we demonstrate that this hypothesis provides an explanation of the double Z+-like peaking structures, which were studied by LHCb with much higher statistics. While according to our hypothesis, the origin of the peaking structures is purely kinematical, reflecting the presence of a conventional resonance in the hidden intermediate state, the amplitude of the Z(4430)+ peak carries a Breit-Wigner-like complex phase, arising from the intermediate Ds\, - resonance. Thus, our hypothesis is entirely consistent with the recent LHCb measurement of the resonant-like amplitude behaviour of the Z(4430)+. We perform a toy fit to the LHCb data, which illustrates that our approach is also consistent with all the observed structure in the LHCb M(π+) spectrum. We suggest a critical test of our hypothesis that can be performed experimentally.