Abstract
In this work, we study the $S$, $P$ and $D$ wave resonance contributions to three-body decays $B_{(s)} \to [ D^{(*)}, \bar{D}^{(*)} ] K^+K^-$ by employing the perturbative QCD (PQCD) approach, where the kaon-kaon invariant mass spectra are dominated by the $f_0(980),f_0(1370),$ $\phi(1020),\phi(1680),f_2(1270),f^{\prime}_2(1525),f_2(1750)$ and $f_2(1950)$ resonances. The $KK$ $S$-wave component $f_0(980)$ is modeled with the Flatt\'e formalism, while other resonances are described by the relativistic Breit-Wigner (BW) line shape. The corresponding decay channels are studied by constructing the kaon-kaon distribution amplitude $\Phi_{KK}$, which captures important final state interactions between the kaon pair in the resonant region. We found that the PQCD predictions for the branching ratios for most considered decays agree with currently available data within errors. The associated polarization fractions of those vector-vector and vector-tensor decay modes are also predicted, which are expected to be tested in the near future experiments. The invariant mass spectra for the corresponding resonances in the $B_{(s)} \to [D^{(*)}, \bar{D}^{(*)} ] K^+K^-$ decays are well established, which can be confronted with the precise data from the LHCb and Belle II experiments.
Highlights
We study the S, P, and D wave resonance contributions to three-body decays BðsÞ → 1⁄2DðÃÞ; DðÃÞKþK− by employing the perturbative quantum chromodynamics (QCD) (PQCD) approach, where the kaon-kaon invariant mass spectra are dominated by the f0ð980Þ, f0ð1370Þ, φð1020Þ, φð1680Þ, f2ð1270Þ, f02ð1525Þ, f2ð1750Þ, and f2ð1950Þ resonances
We found that the PQCD predictions for the branching ratios for most considered decays agree with currently available data within errors
Studies of nonleptonic B meson decays are crucial for testing the standard model (SM), understanding the quantum chromodynamics (QCD), and searching for the possible new physics beyond the SM
Summary
Studies of nonleptonic B meson decays are crucial for testing the standard model (SM), understanding the quantum chromodynamics (QCD), and searching for the possible new physics beyond the SM. Three-body B meson decay modes do receive the entangled resonant and nonresonant contributions, as well as the possible final-state interactions [36,37,38], whereas the relative strength of these contributions varies significantly in different regions of the Dalitz plots [39,40]. The central region corresponds to the case where all three final particles fly apart with similar large energy and none of them moves collinearly to any other This situation contains two hard gluons and is power and αs suppressed with respect to the amplitude at the edge. The central part of the edges corresponds to the case in which two particles move collinearly and the other particle recoils back: this is called the quasi-two-body decay This situation exists in the low ππ or Kπ or KK invariant mass region of the Dalitz plot. The Appendix collects the explicit PQCD factorization formulas for all the decay amplitudes
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