Neutrinoless Double Beta Decay from Lattice QCD: The Long-Distance π- → π+ e- e- Amplitude

Abstract

Neutrinoless double beta decay (\( 0 β β \)) is a hypothetical nuclear decay mode with important implications. In particular, observation of this decay would demonstrate that the neutrino is a Majorana particle and that lepton number conservation is violated in nature. Relating experimental constraints on \(0 β β\) decay rates to the neutrino masses requires theoretical input in the form of non-perturbative nuclear matrix elements which remain difficult to calculate reliably. This work marks a first step toward providing a general lattice QCD framework for computing long-distance \(0 β β\) matrix elements in the case where the decay is mediated by a light Majorana neutrino. The relevant formalism is developed and then tested by computing the simplest such matrix element describing an unphysical \( π- → π+ e- e- \) transition on a series of domain wall fermion ensembles. The resulting lattice data is then fit to next-to-leading-order chiral perturbation theory, allowing a fully-controlled extraction of the low energy constant governing the transition rate, \(gπ π(μ = 770 \,\, MeV) = -10.78(12) stat(51) sys\). Finally, future prospects for calculations of more complicated processes, such as the phenomenologically important \(n0 n0 → p+ p+ e- e-\) decay, are discussed.