Neutrinoless double-beta decay of 76Ge and 130Te. A correction of the neutrinoless 2\b{eta}-decay model and a reanalysis of QUORICINO results

TL;DR

This paper proposes a correction to the neutrinoless double-beta decay model, predicts a shifted signal, and reanalyzes experimental data, providing evidence supporting the decay process and the correction's validity.

Contribution

It introduces a new correction to the decay model, predicts signal shifts, and reanalyzes data to support the decay observation and model accuracy.

Findings

Predicted energy shifts for 76Ge, 100Mo, 130Te.

Reanalysis indicates a signal consistent with neutrinoless double-beta decay.

Supported the validity of the proposed model correction.

Abstract

A correction of the neutrinoless 2\b{eta}-decay model was proposed which predicted a shift of the 2\b{eta}0{\nu}-signal from the Q value (2\b{eta}-decay energy). The shifts were calculated for 76Ge (\D{elta}E=-2.6 keV), 100Mo (\D{elta}E=-4.7 keV), 130Te (\D{elta}E=-3.7 keV). The calculations for 76Ge were in agreement with H-M results. A reanalysis of the published Quoricino data (a search for a 2\b{eta}0{\nu}-decay of 130Te) was performed. It indicated a presence of a signal at E = 2523.5 keV \a{pprox} Q(130Te)-3.7 keV. It could be attributed to the 130Te neutrinoless 2\b{eta}-decay with T1/2 = (5.7+-2.3)10^23 y. A comparison of the H-M and Quoricino data has strongly supported the experimental observation of the 2\b{eta}0{\nu}-decay process and a validity of the proposed correction.