Parity Nonconservation in Hydrogen Induced by Low-Mass Vector-Boson Exchange

Abstract

Parity-nonconserving (PNC) effects in atoms produced by Z-boson exchange between the electron and the nucleus grow rapidly with the nuclear charge Z. If a hypothetical additional Z' boson is light, however, its contribution does not exhibit the same strong enhancement with Z. As a result, the ratio of the low-mass Z' contribution to the Standard Model Z-boson contribution increases rapidly with decreasing Z, in fact faster than 1/Z2. Hydrogen has a further important advantage: its theoretical description is substantially cleaner than that of heavy atoms, allowing a more accurate interpretation of experimental results. For these two reasons, hydrogen and deuterium PNC experiments may provide an especially favorable setting in which to disentangle a possible Z' contribution from the Standard Model background. In this paper we calculate the ratio of the Z'-boson contribution, for arbitrary Z' mass, to the Standard Model Z-boson contribution to parity violation in hydrogen and deuterium, including both nuclear-spin-independent (NSI) and nuclear-spin-dependent (NSD) interactions.