the installation of the feiser collaboration for detecting neutrinos in switzerland was created fromipment that remained from previous experiments was placed in one of the side service rooms. corridors of the collider, thanks to this, scientists have managed to catch more than 150 nitrine, according to experts, the registered particles have the highest energy ever obtained in laboratory conditions in order to register these two experiments were built factors and the cis which is actually the detector , which is detected by netrinos, that is , the new installation is also designed to search for new particles of unknown dark matter, before this experiment scientists recorded. mostly low neutrinos energies coming primarily from the sun, however, according to numerous studies from the depths of space. phantom particles with ultra-high energies comparable to scalider ones come to us. and now work with neutrinos begins in a completely new energy range, which has not been available until now. there is a possibility that among the tounds-mion and electron neutrinos, relicts of the most elusi

the feiser collaboration facility for detecting neutrinos in switzerland was created from components from past experiments. the equipment was placed in one of the side service corridors of the calider thanks to this. we have already managed to catch more than 150, nitrine, according to experts, registered particles have the highest energy ever obtained in laboratory conditions in order to in order to register these, these two experimentalists and the cis were built , which in fact is a detector that detects netrinos, that is, the new installation is also designed to search for new particles of dark matter that no one understands. before this experiment, scientists recorded. mostly low-energy neutrinos, coming primarily from the sun, however, according to numerous studies from the depths of space. phantom particles with ultra-high energies comparable to scalider ones are coming to us and now we are working with neutrinos begins a completely new energy range that has not been available until now . the probability that among the ton ion and electron neutrinos the most elusive and most i

feiser took on this task, the joint institute for nuclear research and registration events interact with netrinos using electronic detectors. well, there is a nuclear emulsion detector, and it is also designed to register nitrine, and of all three types, the new principle of detecting neutrinos can complement our understanding of these mysterious particles, which are the most common in the universe. just imagine, every second , trillions of nitrine fly through us . particles that arise during uh, radiative decay. uh, together with the electron one appears, irina, together with the positron, not three, yes, and in this sense, this is a particle that we kind of deal with every day, but we just don’t notice them at all. the fact is that not trines interact very very weakly; it flies through ordinary matter and very rarely does anyone from within simply interact, that is , we can only detect three of them after this particle has entered the atomic nucleus, which very small that is why the probability that there will be neutrinos. interact with matter is very small, yet scientists have long t