Abstract
In this work, we perform a combined analysis of the $R(D)$, $R(D^*)$, and $R(J/\psi)$ anomalies in a model-independent manner based on the general framework of the four-fermion effective field theory, paying special attention to the use of the hadronic form factors. For the $B\to D(D^*)$ transition form factors, we use the HQET parametrization that includes the higher order corrections of $\mathcal{O}(\alpha_s,\Lambda_{\mathrm{QCD}}/m_{b,c})$ and was determined recently from a fit to lattice QCD and light-cone sum rule results in complementary kinematical regions of the momentum transfer. For the $B_c\to J/\psi(\eta_c)$ transitions, we use the form factors calculated in the covariant light-front quark model, which are found to be well consistent with the preliminary lattice results. With this particular treatment of hadronic matrix elements, in our analysis the two classes of vector operators are shown to be the most favored single new physics (NP) operators by the current experimental constraints within $2\sigma$ and the LEP1 data on $Br(B_c\to \tau\nu)$ as well as the minimum $\chi^2$ fit, while the tensor operator is also allowed but severely constrained, and the scalar ones are excluded. Using the favored ranges and fitted values of the Wilson coefficients of the single NP operators, we also give a prognosis for the physical observables such as the ratios of decay rates ($R(D(D^*)), R(J/\psi(\eta_c))$) and other polarized observables as well as the $q^2$ distributions.
Highlights
The imprints of new physics (NP) beyond the standard model (SM) can be examined via both the direct approach and the indirect approach
We have studied the new physics effects in the b → cτν transitions within the framework of effective field theory, by performing a combined model-independent analysis based on the experimental data of the semitauonic B → DðÃÞτν and Bc → J=ψτν decays
We adopted a set of B → DðÃÞ form factors recently determined by performing a global fit of the heavy quark field theory (HQET) parametrization including higher-order αs and ΛQCD=m contributions to the lattice and light-cone sum rule (LCSR) results and imposing the strong unitarity constraints
Summary
The imprints of new physics (NP) beyond the standard model (SM) can be examined via both the direct approach (probing for NP signals) and the indirect approach (precisely testing the SM). To perform a reliable analysis, we carefully consider the use of the hadronic form factors for both the B → DðDÃÞ and Bc → J=ψðηcÞ transitions. For the former, the heavy quark field theory (HQET) parametrization of the form factors are used in most of the existing experimental and theoretical analyses due to the lack of experimental data to precisely determine them. Using the obtained favored ranges and fitted results for the Wilson coefficients, we give predictions for the physical observables including the ratio of the decay rates, τ longitudinal polarization, final-state vector-meson polarization, and the forwardbackward asymmetry as well as the corresponding q2 distributions.
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