Exploring new physics in the angular distribution of B→ D*(→ Dπ)τ-(→ V-ντ)ντ

Abstract

The decays B→ D*τ-ντ provide sensitive probes of new physics in the b→ cτν transition. We discuss the effects of new physics in the decay chain B→ D*(→ Dπ)τ-(→ V-ντ)ντ where V is a vector meson. We first present a comprehensive analysis of the five-dimensional angular distribution for the full decay chain B→ D*(→ Dπ)τ-(→ ρ-ντ)ντ, exploiting the hadronic τ decay to ρ-ντ to circumvent the experimental challenge of direct τ reconstruction. The differential decay rate is expressed in terms of measurable kinematic variables θ*, Eρ, θρ, χρ, and q2 -- with complete coefficient functions provided for scalar, pseudoscalar, vector, axialvector, and tensor new-physics interactions. From this distribution we construct a set of integrated observables, including the D* polarization fractions and lepton-side forward-backward and azimuthal asymmetries, which isolate distinct combinations of helicity amplitudes. We further perform a numerical analysis using current experimental data on RD* and the D* longitudinal polarization fraction FLD* to constrain the complex new-physics couplings gL, gR, gP, and gT, revealing the correlations among them. Our formalism is also applicable to τ a1 ντ, where the 3π final states mainly come from the a1 meson. The framework established here provides a powerful tool for disentangling new-physics scenarios with future high-statistics data.