Test of Nuclear Decay Rate Variation due to an Antineutrino Flux

Abstract

Unexplained variations of the decay rate for weak interaction decays such as β-decay, electron capture, as well as strong interaction α-decay have been reported. Some researcher interpreted these variations as caused by an unexplained fundamental interaction. The purpose of the paper is to review decay rate parameter variations experiments and place them into a common comparable context and to make decay parameter measurements at the level of 10-5 in the presences of an antineutrino flux, 3 ×1012 \, cm-2 \, sec-1, 6.5 meters from the High Flux Isotope Reactor(HFIR) reactor core having an on-off cycle time of 30 days. Two weak interaction decays, one via electron capture and the other via β- decay were selected because the final state and the time reverse state each contain a neutrino and anti-neutrino, covering arguments that the anti-neutrino flux may interact differently or not at all in one of the cases. The experiment searched for variation of the 5425Mn, e- capture and 137~55Cs, β- decay rate parameters. The measured variation in the decay rate parameters are found to be δ λ/ λ = (0.034 1.38)× 10-5 for 5425Mn and δ λ/ λ = (0.67 1.56)× 10-5 for 137~55Cs. These results are consistent with no measurable decay rate parameter variation due to an antineutrino flux, yielding a 68\% confidence level upper limit sensitivity for 5425Mn, δ λ/ λ ≤ 1.31×10-5 or σ ≤ 1.29×10-25\,cm2 in cross section and for 137~55Cs, δ λ/ λ ≤ 2.23×10-5 or σ ≤ 5.69×10-27\,cm2. These null or no observable effect measurements places cross-section upper limits 104 times more sensitive than past experiments.