Stereo scientists refute the existence of sterile neutrons

On the  January 12, 2023
Illustration de l'expérience STEREO réalisée par Loris Scola. La vue en coupe du détecteur montre les différentes couches de blindage mises en place pour atténuer le bruit de fond extérieur. Le cœur du détecteur est constitué de 6 cellules identiques disp
Illustration de l'expérience STEREO réalisée par Loris Scola. La vue en coupe du détecteur montre les différentes couches de blindage mises en place pour atténuer le bruit de fond extérieur. Le cœur du détecteur est constitué de 6 cellules identiques disposées entre 9 et 11 m du cœur compact de l’ILL, rendu visible ici par l’intense lumière Cerenkov qu’il induit dans l’eau de la piscine du réacteur. Les interactions des neutrinos induisent d’infimes flashs lumineux dans le liquide scintillant qui remplit les cellules, dont les murs réfléchissants permettent de collecter la lumière jusqu’aux photomultiplicateurs installés au sommet. Au-dessus de STEREO un large canal, rempli de 6 m d’eau et connecté à la piscine offre une protection cruciale contre les rayonnements cosmiques.
Stereo, the collaboration between the CEA, CNRS, the Université Grenoble-Alpes (UGA), the Université Savoie Mont Blanc (USMB), the Institut Laue-Langevin (ILL), and the Max Planck Institut für Kernphysik (MPIK), has found no proof that the sterile neutrino exists after six years of experimentation. Their conclusion will impact numerous branches of physics, with their study to be published on 12 January in Nature.
The physicists involved in the Stereo collaboration are unequivocal: the sterile neutrino is not responsible for the anomaly in neutrinos emitted by nuclear reactors. The Stereo team, which includes scientists from the CEA, CNRS, UGA, USMB, ILL and MPIK, has been relentless in its search for this particle for the past six years, without having found anything to prove its existence during the neutrino oscillation experiment using the Stereo detector designed to study neutrinos produced in the ILL test reactor.

This experiment brings years of questioning to an end. The existence of the sterile neutrino stems from the natural extrapolation of the standard model developed by particle physicists in the second half of the 21st century. This particle would provide an explanation to some still poorly understood physical phenomena, such as black matter. Physicists believed they had detected the sterile neutrino in several past experiments in nuclear reactors when they realised that fewer neutrinos had been produced during fission than predicted by their models.
To test the assumption whether sterile neutrinos exist and determine their properties, researchers in the Stereo team decided to use a very strong source of neutrinos, those produced in the high-flux reactor at the ILL in Grenoble. A series of six identical detectors were installed only ten metres from the reactor core to collect data, with the team already benefiting from a wealth of knowledge accumulated over several decades of experiments. Protected from any unwanted signals in the surrounding environment, these detectors were ideally positioned to detect the signature of sterile neutrinos with unparalleled sensitivity: much more than a simple deficit in standard neutrinos, a conversion in their energy distribution was expected to be found. “This deficit in reactor neutrinos exacerbated other anomalies observed in previous experiments. The sterile neutrino was considered a potential breakthrough in particle physics and we believed it was within our reach; we were wholly invested in this adventure,” explained David Lhuillier, a CEA physicist and representative of the collaboration. Over a period of 4 years between 2017 and 2020, followed by another 2 years of data analysis, a total of 107,558 neutrinos were observed without a single trace of a sterile neutrino.

Researchers will now have to find another way to explain this deficit in the number of neutrinos emitted during the radioactive decay of fission products. The accuracy of the Stereo measurements is so precise that the team began to look in another direction: it seems it is not the experiments that detect the neutrinos that would be biased, but rather the nuclear data used to predict radioactive decay.

The energy distribution of neutrinos resulting from the fission of uranium-235 measured by Stereo has therefore become the reference data, which is driving a vast programme to reassess the beta emissions of fission products described in the nuclear databases. For instance, this programme will allow us to more accurately understand the phenomena coming into play during the shutdown of either a current or future nuclear reactor. The results of the Stereo collaboration also provide a solid foundation on which to base the next series of experiments in reactor environments, whether for reactor monitoring by measuring the neutrinos emitted, for studying the neutrino mass hierarchy, or for further testing the standard low-energy model.

Stereo is a joint French-German experiment developed and carried out by a team of scientists from the CEA-IRFU in Saclay, the ILL Institute in Grenoble, the CNRS-USMB LAPP laboratory in Annecy, the CNRS-UGA LPSC laboratory in Grenoble, and the MPIK Institute in Germany.
Published on  January 12, 2023
Updated on  January 12, 2023