$Λ_b \to Λ_c τ\barν_τ$ Decay in the Standard Model and with New Physics (1502.07230v4)

Abstract: Recently hints of lepton flavor non-universality emerged when the BaBar Collaboration observed deviations from the standard model predictions in $R(D^{(*)}) \equiv {\cal B}({\bar B} \to D^{(*)+} \tau^- {\bar\nu}\tau) / {\cal B}({\bar B} \to D^{(*)+} \ell^- {\bar\nu}\ell)$ ($\ell =e,\mu$). Another test of this non-universality can be in the semi leptonic $\Lambda_{b}\to\Lambda_{c}\tau\bar{\nu}{\tau}$ decay. In this work we present predictions for this decay in the standard model and in the presence of new-physics operators with different Lorentz structures. We present the most general four-fold angular distribution for this decay including new physics. For phenomenology, we focus on predictions for the decay rate and the differential distribution in the momentum transfer squared $q^2$. In particular, we calculate $R{\Lambda_{b}} = \frac{BR[\Lambda_b \to \Lambda_c \tau \bar{\nu}{\tau}]}{BR[\Lambda_b \to \Lambda_c \ell \bar{\nu}{\ell}]}$ where $\ell$ represents $\mu$ or $e$, and find the standard model prediction to be around $0.3$ while the new physics operators can increase or slightly decrease this value.