Radiative corrections to nucleon weak charges and Beyond Standard Model impact

Abstract

The nucleon axial charge is a central ingredient in nuclear and particle physics, and a key observable in precision tests of the electroweak Standard Model sector and beyond. We report on the first complete calculation of its electroweak quantum corrections up to O(α), using a combination of current algebra techniques and QCD sum rules. We find a substantial enhancement due to the weak magnetism contribution in the elastic channel, and include higher-twist and target mass corrections at low Q2 to find RA = 0.02881(22). Using analogous methods, we determine a new value for the vector charge renormalization, RV = 0.02474(27), and show how the two most recent calculations can be brought into agreement. This allows us to determine a corrected experimental gA0 = 1.2730(13), which is a >2σ shift away from the commonly quoted value. We use this new result to set constraints on exotic right-handed currents by comparing to lattice QCD results, and resolve a double-counting issue in the |Vud| extraction from mirror decays.