Impact of polarization observables and Bc τ on new physics explanations of the b c τ anomaly

Abstract

The combined analysis of the BaBar, Belle, and LHCb data on B Dτ, B D*τ and Bc J/τ decay observables shows evidence of physics beyond the Standard Model (SM). In this article, we study all the one- and two-dimensional scenarios which can be generated by adding a single new particle to the SM. We put special emphasis on the model-discriminating power of FL(D*) and of the τ polarizations, and especially on the constraint from the branching fraction BR(Bcτ). We critically review this constraint and do not support the aggressive limit of BR(Bcτ)<10\% used in some analyses. While the impact of FL(D*) is currently still limited, the BR(Bcτ) constraint has a significant impact: depending on whether one uses a limit of 60\%, 30\% or 10\%, the pull for new physics (NP) in scalar operators changes drastically. More specifically, for a conservative 60\% limit a scenario with scalar operators gives the best fit to data, while for an aggressive 10\% limit this scenario is strongly disfavored and the best fit is obtained in a scenario in which only a left-handed vector operator is generated. We find a sum rule for the branching ratios of B Dτ, B D*τ and b cτ which holds for any NP contribution to the Wilson coefficients. This sum rule entails an enhancement of BR(b cτ) over its SM prediction by (24 6)\% for the current R(D(*)) data.