The NOvA detector measures 50 feet by 50 feet by 200 feet, and the top surface of the detector as shown here is covered with readout and monitoring systems. Each gold-colored box in the image contains a photodiode array, cooling components, and associated electronics to detect light from 32 of the 344,000 cells that make up the detector. Credit: Reidar Hahn/Fermilab
Every second, trillions of neutrinos travel through your body unnoticed. Neutrinos are among the most abundant particles in the universe, but they are difficult to study because they very rarely interact with matter. To find traces of these elusive particles, researchers from Caltech have collaborated with 39 other institutions to build a 14,000-ton detector the size of 2 basketball courts called NuMI Off-Axis Electron Neutrino Appearance, or NOvA.
The experiment aims to observe neutrino oscillations – or the conversion of one type of neutrino into another – to learn about the subatomic composition of the universe. There are 3 different types, or “flavors,” of neutrinos – muon-, tau-, and electron-type. The NOvA experiment has made successful detections of the transformation of muon-type neutrinos into electron-type neutrinos. Discovering more about the frequency and nature of neutrino oscillations is an important step to determining the masses of different types of neutrinos, a crucial unknown component in every cosmological model of the universe.
Though neutrinos rarely interact with matter, 1 in every 10 billion neutrinos that passes through the detector will interact with an atom in the detector. To observe these collisions, a beam of neutrinos 500 miles away at Fermilab in Chicago is fired every 1.3s in a 10-ms burst at the detector. The detector is made up of 344,000 cells, each like a pixel in a camera and each filled with a liquid scintillator, a chemical that emits light when electrically charged particles pass through it. When a neutrino smashes into an atom of this liquid – an event estimated to happen once for every 10 billion neutrinos that pass through – it produces a distinctive spray of particles, such as electrons, muons, or protons. When these particles pass through a cell, fluorescent chemicals light up the cell, allowing scientists can track the paths of the particles from the collision.
“Each type of neutrino leaves a particular signature when it interacts in the detector,” says Assistant Prof Ryan Patterson. “Fermilab makes a stream of almost exclusively muon-type neutrinos. If one of these hits something in our detector, we will see the signatures of a particle called a muon. However, if an electron-type neutrino interacts in our detector, we see the signatures of an electron.” Because the beam of neutrinos coming from Fermilab is designed to produce almost entirely muon-type neutrinos, there is a high probability that any signatures of electron-type neutrinos come from a muon-type neutrino that has undergone a transforming oscillation.
Researchers estimated that if oscillations were not occurring, 201 muon-type neutrinos would have been measured over the initial data-taking period, which ended in May 2015. But during this first data-collection run, NOvA saw the signatures of only 33 muon-type neutrinos – suggesting that muon-type neutrinos were disappearing because some had changed type. The detector also measured 6 electron-type neutrinos, when only one of this type would be expected if oscillations were not occurring.
“We see a large rate for this transition, much higher than it needed to be, given our current knowledge,” Patterson says. “These initial data are giving us exciting clues already about the spectrum of neutrino masses.”
The Caltech NOvA team led the research and development on the detector elements. The goal was to make each detector cell sensitive enough to identify the faint particle signals over background noise. The team designed the individual detector elements to operate at -15 degrees Celsius to keep noise — aberrant vibrations and other signals in the data — at a minimum, and also built structures to remove the condensation that can occur at such low temperatures. By the end of construction in 2014, all 12,000 detector arrays, each serving 32 cells, had been built at Caltech.
“We know that two of the neutrinos are similar in mass, and that a third has a rather different mass from the other two. But we still do not know whether this separated mass is larger or smaller than the other two,” Patterson says. Through precise study of neutrino oscillations with NOvA, researchers hope to solve this mass-ordering mystery. “The neutrino mass ordering has connections throughout physics, from the growth of structure in the universe to the behavior of particles at inaccessibly high energies,” he says, with NOvA unique among operating experiments because of its sensitivity to this mass ordering.
In the future, researchers at NOvA plan to determine if antineutrinos oscillate at the same rate as neutrinos – that is, to see if neutrinos and antineutrinos behave symmetrically.
http://www.caltech.edu/news/probing-transforming-world-neutrinos-50435
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