Probing new physics in the Neutrinoless double beta decay using electron angular correlation

Abstract

The angular correlation of the electrons emitted in the neutrinoless double beta decay (02β) is presented using a general Lorentz invariant effective Lagrangian for the leptonic and hadronic charged weak currents. We show that the coefficient K in the angular correlation d/d θ (1-K θ) is essentially independent of the nuclear matrix element models and present its numerical values for the five nuclei of interest (76Ge, 82Se, 100Mo, 130Te, and 136Xe), assuming that the 02β-decays in these nuclei are induced solely by a light Majorana neutrino, M. This coefficient varies between K=0.81 (for the 76Ge nucleus) and K=0.88 (for the 82Se and 100Mo nuclei), calculated taking into account the effects from the nucleon recoil, the S and P-waves for the outgoing electrons and the electron mass. Deviation of K from its values derived here would indicate the presence of New Physics (NP) in addition to a light Majorana neutrino, and we work out the angular coefficients in several M + NP scenarios for the 76Ge nucleus. As an illustration of the correlations among the 02β observables (half-life T1/2, the coefficient K, and the effective Majorana neutrino mass |< m>|) and the parameters of the underlying NP model, we analyze the left-right symmetric models, taking into account current phenomenological bounds on the right-handed WR-boson mass and the left-right mixing parameter ζ.