Reactor Neutrino Experiments: θ13 and Beyond

Abstract

We review the current-generation short-baseline reactor neutrino experiments that have firmly established the third neutrino mixing angle θ13 to be non-zero. The relative large value of θ13 (around 9) has opened many new and exciting opportunities for future neutrino experiments. Daya Bay experiment with the first measurement of m2ee is aiming for a precision measurement of this atmospheric mass-squared splitting with a comparable precision as m2μμ from accelerator muon neutrino experiments. JUNO, a next-generation reactor neutrino experiment, is targeting to determine the neutrino mass hierarchy with medium baselines (50 km). Beside these black opportunities enabled by the large θ13, the current-generation (Daya Bay, Double Chooz, and RENO) and the next-generation (JUNO, RENO-50, and PROSPECT) reactor experiments, with their unprecedented statistics, are also leading the precision era of the 3-flavor neutrino oscillation physics as well as constraining new physics beyond the neutrino Standard Model.