Radiative corrections to two-neutrino double-beta decay

TL;DR

This paper derives a universal radiative correction factor for two-neutrino double-beta decay using effective field theory, highlighting its importance for precise nuclear and Standard Model tests.

Contribution

It introduces the first derivation of a double-weak Sirlin function, a universal radiative correction factor for double-beta decay, independent of nuclear matrix elements.

Findings

The double-weak Sirlin function depends on electron energies and angles.

Nuclear-structure-dependent corrections are negligible at current sensitivities.

Radiative corrections significantly affect electron spectra and should be included in analyses.

Abstract

We use heavy-nucleus effective field theory to compute radiative corrections to two-neutrino double-$\beta$ decay ($2\nu\beta\beta$). Our main result is the first derivation of a universal radiative-correction factor for double-weak decays -- the analogue of the Sirlin function in single-$\beta$ decay -- independent of nuclear matrix elements and excitation energies. This "double-weak Sirlin function" depends on the individual electron energies as well as their relative angle and differs significantly from the approximation obtained by summing two single-$\beta$ decay Sirlin functions. In addition, we calculate the nuclear-structure-dependent component of the radiative corrections and find that they can still be neglected at current experimental sensitivities. On the other hand, the double-weak Sirlin function induces distortions of the electron energies and angular spectra that are comparable in size to the leading nuclear-structure corrections parametrized by the ratio of nuclear matrix elements, $\xi_{31}$. Our results indicate that extractions of nuclear structure information and tests of the Standard Model from high-precision $2\nu\beta\beta$ measurements must include double-weak radiative corrections, implying that recent extractions of $\xi_{31}$ should be revisited.