The positron quickly annihilated with an electron, releasing a gamma ray, while the neutron was captured by a cadmium nuclei, itself releasing a gamma ray a few microseconds later. This reaction saw the proton turn into a neutron, and the antineutrino forming a positron. Antineutrinos from a nuclear reactor underwent an “inverse beta decay” with protons in the water. Two targets were created, using a solution of cadmium chloride in water, with scintillation detectors placed next to the targets. The first successful neutrino detection was achieved in 1956 by Frederick Reines and Clyde Cowan. These ultralight uncharged particles interact with matter so rarely that detecting them requires a rather specialized experimental setup. You’d think being so common would make these particles easy to find, but it’s anything but the case. Modern physics tells us that around 100 trillion neutrinos pass through your body every second. In this article, we’ll take a closer look at how these detectors work and some of the most notable examples of neutrino detectors in the world today. These detectors come in a few different flavors, each employing its unique method to spot these elusive particles. Neutrinos interact with matter so rarely that it takes a very special kind of detector to catch them in the act. Despite their elusive nature, scientists are keen to detect neutrinos as they can provide valuable information about the processes that produce them. They are produced in abundance by the sun, as well as by nuclear reactions on Earth and in supernovae. These tiny subatomic particles have no electric charge and an extremely small mass, making them incredibly difficult to detect. Neutrinos are some of the most elusive particles that are well-known to science.
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