Laboratory constraint on the electric charge of the neutron and the neutrino

Abstract

We revisit constraints on the electric charge of the neutron and neutrino as well as on ep+ee. We consider phenomenological constraints based on laboratory study of the electrical neutrality of subatomic, atomic, and molecular species under assumption of the conservation of the electric charge in the beta decay, that relates ep+ee, en, and enu. Some previously published constraints utilized an additional assumption enu=0, which we do not. We dismiss a cosmological constraint at the level of 10-35 e utilized by PDG in their Review of particle properties as a controversial one which makes the laboratory constraints on enu dominant. The phenomenological constraints from the laboratory experiments are obtained as ep+ee=(0.22.6)10-21 e, en=(-0.41.1)10-21 e, and enu=(0.63.2)10-21 e. The ones on ep+ee and en are at the same level as the PDG constraints, while our enu constraint is several orders of magnitude weaker than the controversial cosmological result dominated in the PDG constraint, but several orders of magnitude stronger than the other individual enu constraints considered by PDG. We also consider consistency of the phenomenological constraints and the SM. The SM ignores the neutrino mass term and cannot describe the neutrino oscillations which makes it not a complete theory but a part of it. We demonstrate that the condition of the cancellation of the triangle anomaly within the complete theory does not disagree with the phenomenological constraints since different extensions of the SM may produce different additional contributions to the anomaly. In particular, we consider a minimal extension of the SM, where leptons (nu,e) are treated the same ways as quarks, which sets ep+ee=0 and allows for numerical strengthening the constraint on en and enu, which is en=-enu=(-0.41.0)10-21 e.