The ratio $\mathcal{R}(D_s)$ for $B_s \to D_s \ell\nu_\ell$ by using the QCD light-cone sum rules within the framework of heavy quark effective field theory

TL;DR

This paper calculates the $B_s o D_s$ transition form factors using light-cone sum rules within heavy quark effective theory, leading to a precise prediction of the ratio $ (D_s)$ relevant for semileptonic decays.

Contribution

It provides a novel calculation of $B_s o D_s$ form factors using a chiral current approach within HQET, with improved accuracy and extrapolation methods.

Findings

Transition form factors at zero recoil: $f_{+,0}^{B_s o D_s}(0)=0.533^{+0.112}_{-0.094}$

Predicted ratio $ (D_s)=0.334 o 0.017$

Branching fractions for $B_s$ semileptonic decays.

Abstract

In the paper, we study the $B_s\to D_s$ transition form factors by using the light-cone sum rules within the framework of heavy quark effective field theory. We adopt a chiral current correlation function to do the calculation, the resultant transition form factors $f_+^{B_s\to D_s}(q^2)$ and $f_0^{B_s\to D_s}(q^2)$ are dominated by the contribution of $D_s$-meson leading-twist distribution amplitude, while the contributions from less certain $D_s$-meson twist-3 distribution amplitudes are greatly suppressed. At the largest recoil point, we obtain $f_{+,0}^{B_s \to D_s}(0)=0.533^{+0.112}_{-0.094}$. By further extrapolating the transition form factors into all the physically allowable $q^2$ region with the help of the $z$-series parametrization approach, we calculate the branching fractions $\mathcal{B}(B_s \to D_s \ell^\prime \nu_{\ell^\prime})$ with $(\ell^\prime= e,\mu)$ and $\mathcal{B}(B_s \to D_s \tau \nu_\tau)$, which gives $\mathcal{R}(D_s)=0.334\pm 0.017$.