Quasi-two-body decays $B_{(s)}\to K^*(892)h\to K\pi h$ in perturbative QCD approach

TL;DR

This paper analyzes quasi-two-body decays of B mesons into K*(892) resonances using perturbative QCD, calculating branching ratios and CP asymmetries, and fitting distribution amplitude parameters to experimental data.

Contribution

It extends previous work to kaon-pion cases, employing a parameterized distribution amplitude and Breit-Wigner formula, providing predictions consistent with experimental data.

Findings

Calculated branching ratios and CP asymmetries match experimental results.

Determined Gegenbauer moments of the P-wave kaon-pion distribution amplitudes.

Predictions will be tested by LHCb and Belle II experiments.

Abstract

We extend our recent works on the $P$-wave two-pion resonant contributions to the kaon-pion cases in the hadronic charmless $B$ meson decays by employing the perturbative QCD approach. The concerned decay modes are analysed in the quasi-two-body framework by parameterizing the kaon-pion distribution amplitude $\Phi_{K \pi}^{\rm P}$, which contains the final state interactions between the kaon and pion in the resonant region. The relativistic Breit-Wigner formula for the $P$-wave resonant state $K^*(892)$ is adopted to parameterize the time-like form factor $F_{K\pi}$. We calculate the $CP$-averaged branching ratios and direct $CP$-violating asymmetries of the quasi-two-body decays $B_{(s)}\to K^*(892) h\to K\pi h$, with $h=(\pi, K)$, in this work. It is shown that the agreement of theoretical results with the experimental data can be achieved, through which Gegenbauer moments of the $P$-wave kaon-pion distribution amplitudes are determined. The predictions in this work will be tested by the precise data from the LHCb and the future Belle II experiments.