Branching ratios and CP asymmetries of $B^0 \to η_c f_0$ in the improved perturbative QCD formalism
Abstract
Motivated by the idea of fragmented scalar glueball, we investigate the decays $B^0 \to \eta_c f_0$ within the improved perturbative QCD (iPQCD) framework by including the known next-to-leading order corrections. Here, $B^0$ and $f_0$ denote the neutral $B_{d,s}^0$ mesons and the light scalar mesons $f_0(500, 980, 1370, 1500)$ under the $q\bar q$ assignment. The {\it CP}-averaged branching ratios (BRs) and the {\it CP} asymmetries of $B^0 \to \eta_c f_0$ are evaluated with the $f_0(500)[f_0(1370)]-f_0(980)[f_0(1500)]$ mixing in quark-flavor basis. For effective comparisons with the near-future measurements, we further derive the $B^0 \to \eta_c f_0 (\to \pi^+ \pi^-/K^+ K^-)$ BRs under the narrow-width approximation. ${\rm BR}(B_s^0 \to \eta_c f_0(980) (\to \pi^+ \pi^-))= (2.87^{+1.38}_{-1.29}) \times 10^{-4}$ obtained in the iPQCD formalism agrees with the available measurements and predictions within uncertainties. Large BRs of $B_s^0 \to \eta_c f_0(1500) (\to \pi^+ \pi^-/K^+ K^-)$ and large direct {\it CP} asymmetries of $B^0 \to \eta_c f_0(1370, 1500)$ are accessible in the LHCb and Belle-II experiments. The experimental tests of these iPQCD predictions would help us to understand the nature of these light scalars more deeply and provide evidences to decipher $f_0(1500)$ as a primary or fragmented scalar glueball potentially.