Testing the dark origin of neutrino masses with oscillation experiments
Abstract
The origin of neutrino masses remains unknown to date. One popular idea involves interactions between neutrinos and ultralight dark matter, described as fields or particles with masses mφ 10\,eV. Due to the large phase-space number density, this type of dark matter exists in coherent states and can be effectively described by an oscillating classical field. As a result, neutrino mass-squared differences undergo field-induced interference in spacetime, potentially generating detectable effects in oscillation experiments. We demonstrate that if mφ 10-14\,eV, the mechanism becomes sensitive to dark matter density fluctuations, which suppresses the oscillatory behavior of flavor-changing probabilities as a function of neutrino propagation distance in a model-independent way, thereby ruling out this regime. Furthermore, by analyzing data from the Kamioka Liquid Scintillator Antineutrino Detector (KamLAND), a benchmark long-baseline reactor experiment, we show that the hypothesis of a dark origin for the neutrino masses is disfavored for mφ 10-14\,eV, compared to the case of constant mass values in vacuum. This result holds at more than the 4σ level across different datasets and parameter choices. The mass range 10-17\,eV mφ 10-14\,eV can be further tested in current and future oscillation experiments by searching for time variations (rather than periodicity) in oscillation parameters.
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