Physics potential of searching for 0ββ decays in JUNO

Abstract

In the past few decades, numerous searches have been made for the neutrinoless double-beta decay (0ββ) process, aiming to establish whether neutrinos are their own antiparticles (Majorana neutrinos), but no 0ββ decay signal has yet been observed. A number of new experiments are proposed but they ultimately suffer from a common problem: the sensitivity may not increase indefinitely with the target mass. We have performed a detailed analysis of the physics potential by using the Jiangmen Underground Neutrino Observatory (JUNO) to improve the sensitivity to 0ββ up to a few meV, a major step forward with respect to the experiments currently being planned. JUNO is a 20 kton low-background liquid scintillator (LS) detector with 3\%/E (MeV) energy resolution, now under construction. It is feasible to build a balloon filled with enriched xenon gas (with 136Xe up to 80\%) dissolved in LS, inserted into the central region of the JUNO LS. The energy resolution is 1.9\% at the Q-value of 136Xe 0ββ decay. Ultra-low background is the key for 0ββ decay searches. Detailed studies of background rates from intrinsic 2ββ and 8B solar neutrinos, natural radioactivity, and cosmogenic radionuclides (including light isotopes and 137Xe) were performed and several muon veto schemes were developed. We find that JUNO has the potential to reach a sensitivity (at 90\% C. L.) to T0ββ1/2 of 1.8×1028 yr (5.6×1027 yr) with 50 tons (5 tons) of fiducial 136Xe and 5 years exposure, while in the 50-ton case the corresponding sensitivity to the effective neutrino mass, mββ, could reach (5--12) meV, covering completely the allowed region of inverted neutrino mass ordering.