Two- and three-body hadronic decays of charmed mesons involving a tensor meson

TL;DR

This paper analyzes D meson decays involving tensor mesons, using form factors from light-cone sum rules and light-front models, highlighting the importance of finite-width effects and the need for more experimental data.

Contribution

It provides a detailed theoretical study of D to tensor-pseudoscalar decays, incorporating vertex corrections and finite-width effects, and compares different form factor models against experimental data.

Findings

Light-cone sum rule form factors better match data.

Finite-width effects significantly impact D decays involving tensor mesons.

Tensor decay constants contribute via vertex and spectator corrections.

Abstract

We study the quasi-two-body $D\to TP$ decays and the three-body $D$ decays proceeding through intermediate tensor resonances, where $T$ and $P$ denote tensor and pseudoscalar mesons, respectively. We employ $D\to T$ transition form factors based upon light-cone sum rules and the covariant light-front quark model to evaluate the decay rates, with the former giving a better agreement with current data. Though the tree amplitudes with the emitted meson being a tensor meson vanish under factorization approximation, contributions proportional to the tensor decay constant $f_T$ can be produced from vertex and hard spectator-scattering corrections. We also investigate the finite-width effects of the tensor mesons and find that, contrary to three-body $B$ decays, the tensor-mediated $D$ decays are more seriously affected and the narrow width approximation has to be corrected. More experimental data are required in order to extract information topological amplitudes associated with quasi-two-body $D\to TP$ decays. Among the data, the $D^+\to f_2\pi^+$ and $D^+\to \bar K_2^{*0}\pi^+$ branching fractions are not self consistent and further clarification is called for.