Improved limits on a new Z' in B-L scenarios with the NA64 experiment at CERN

Abstract

Extensions of the Standard Model featuring an additional U(1)B-L gauge symmetry provide a compelling framework linking the origin of neutrino masses to possible dark matter candidates. The associated gauge boson, Z', couples directly to Standard Model fermions and can be produced in fixed-target experiments through electron-nucleus interactions. In this work, we present new constraints on the coupling constant gB-L obtained with the NA64 experiment using the full electron-beam dataset collected between 2016 and 2022, corresponding to (9.40.5)×1011 electrons on target. The analysis includes the resonant e+e- annihilation production channel, which enhances sensitivity in the mass range mZ'∈[200,300] MeV. The larger dataset provides approximately three times the statistics of previous analyses, thereby improving sensitivity. For the unbroken U(1)B-L case, the new limits exceed those from dedicated neutrino-scattering experiments, providing the most stringent laboratory bounds on gB-L for sub-GeV masses of the new boson. In scenarios where the Z' couples to dark matter, the decay width is dominated by invisible channels, and the corresponding exclusion limits can be directly derived from the NA64 invisible-mode analysis.