Neutrinos are among the strangest known particles, so lightweight that trillions pass through your body every second without a trace. However, for all their invisibility, they carry a mystery that’s kept physicists up at night—where does their tiny, unnoticeable mass come from?
Previously, an intriguing theory proposed that neutrinos gain their tiny masses by interacting with ultralight dark matter. In a recent study, researchers have put this idea to the test using real-world data. Their findings suggest that the dark origin of neutrino mass probably isn’t the answer.
“We conclude that neutrino interactions with scalar dark matter, as proposed in, are unlikely to be the dominant mechanism behind neutrino mass generation,” the study authors note.
This conclusion has further deepened the neutrino mystery. Now, it’s far more likely that neutrino masses come from conventional physics or perhaps new physics, which is completely unrelated to dark matter.
Testing the dark matter interaction theory
The researchers began their study with a simple theory. If neutrinos get their mass by interacting with a form of dark matter made of extremely light particles, lighter than 10 electron volts (one electron weighs about 511,000 eV)? These light particles, likely bosons, could act like gentle waves oscillating across space, affecting the behavior of passing neutrinos.
To test this, the researchers built a theoretical framework that explained how neutrinos would behave if they did interact with such ultralight dark matter. According to their model, the dark matter field would influence neutrinos in two major ways.
First would be time-based changes where the dark matter field, behaving like a slow-moving wave, would cause tiny changes in neutrino mass over time. This depends on the frequency of the wave, which is tied to the mass of the dark matter particles.
In the second, space-based effects, the location of neutrino detectors on Earth, the position of the Sun, and the motion of the planet through space all influence how the neutrino interacts with the oscillating dark matter field.
These factors, the researchers explained, would slightly modify the probabilities of how neutrinos oscillate from one type to another (for example, from an electron neutrino to a muon neutrino). They then compared their predictions with real data from the KamLAND experiment in Japan, a neutrino detector that has gathered years of precise measurements from both natural and artificial sources.
By running simulations and comparing the theoretical signals against KamLAND’s observations, the team looked for any sign that matched the patterns expected from a dark matter-influenced mass origin. They also cross-checked this approach using other neutrino experiments, including those measuring solar neutrinos and short- and long-baseline oscillations (experiments that track neutrinos over various distances).
“We developed a framework in which the smallness of neutrino masses results from their interaction with the dark sector, and then rigorously tested if such a connection can be detected using existing neutrino data, including short- and long-baseline neutrino oscillation experiments and solar neutrino measurements,” Luca Visinelli, one of the study authors, said.
“Our results suggest that such a dark-sector origin for neutrino masses is not supported by current data,” he added.
Have we reached a dead end?
The earlier theory linking neutrino mass to dark matter gave scientists hope that discovering ultralight dark matter would also solve the mystery of neutrino mass. However, the findings from the current study discard this idea and suggest that if such interactions existed, they should have already left detectable fingerprints in the oscillation data, and they haven’t.
This brings us back to zero. Scientists now have no idea what actually gives neutrinos their mass. However, while this might seem like a dead end, it’s actually a major step forward.
By ruling out a popular theory, the study helps scientists narrow down the possibilities and focus their attention on more promising paths, perhaps involving new particles or forces beyond the Standard Model but not connected to dark matter.
Moreover, with upcoming experiments like JUNO in China and DUNE in the US that are expected to deliver even more precise neutrino data, the researchers plan to revisit and refine their model to test other subtle effects. They’re also looking into how similar dark-sector interactions might influence other systems, like atomic clocks or quantum sensors.
The study is published in the journal Physical Review Letters.