Anatomy of $B \to K \eta^{(\prime)}$ decays in different mixing schemes and effects of next-to-leading order contributions in the perturbative QCD approach

TL;DR

This study comprehensively analyzes $B o K o ext{eta}^{( ext{prime})}$ decays using perturbative QCD, highlighting the significance of NLO contributions and different mixing schemes in aligning theoretical predictions with experimental data.

Contribution

It provides the first detailed NLO pQCD calculations for $B o K o ext{eta}^{( ext{prime})}$ decays across multiple mixing schemes, improving agreement with experimental results.

Findings

NLO contributions significantly enhance decay rate predictions.

The $ ext{eta}$-$ ext{eta}^{ ext{'} }$-$G$ mixing scheme best fits the data.

NLO form factor corrections increase branching ratios by about 20%.

Abstract

In this paper we perform a comprehensive study of the four $B \to K \etap$ decays in the pQCD factorization approach. We calculate the CP-averaged branching ratios and CP-violating asymmetries of $B \to K\etap$ decays in the ordinary $\eta$-$\etar$, the $\eta$-$\etar$-$G$, and the $\eta$-$\etar$-$G$-$\eta_c$ mixing schemes. Besides the full LO contributions, all currently known NLO contributions to $B \to K \etap$ decays in the pQCD approach are taken into account. From our calculations and phenomenological analysis, we find the following. (a) The NLO contributions in general can provide significant enhancements to the LO pQCD predictions for the decay rates of the two $B \to K \etar$ decays, around $70%-89%$ in magnitude, but result in relatively small changes to $Br(B \to K \eta)$. (b) Although the NLO pQCD predictions in all three considered mixing schemes agree well with the data within one standard deviation, those pQCD predictions in the $\eta$-$\etar$-$G$ mixing scheme provide the best interpretation for the measured pattern of $Br(B \to K \etap)$: $Br(B^0 \to K^0 \eta) \approx 1.13\times 10^{-6}$, $Br(B^0 \to K^0 \etar) \approx 66.5 \times 10^{-6}$, $Br(B^\pm \to K^\pm \eta) \approx 2.36\times 10^{-6}$, and $Br(B^\pm \to K^\pm \etar) \approx 67.3 \times 10^{-6}$, which agree perfectly with the measured values. (c) The NLO pQCD predictions for the CP-violating asymmetries for the four considered decays are also in good consistent with the data. (d) The newly known NLO contribution to the relevant form factors $\calm_{FF}$ can produce about a 20% enhancement to the branching ratios $Br(B \to K \etar)$, which plays an important role in closing the gap between the pQCD predictions and the relevant data. (e) The general expectations about the relative strength of the LO and NLO contributions from different sources are examined and confirmed by explicit numerical calculations.