The\u00a0Fermi National Accelerator Laboratory<\/strong>‘s international NOvA collaboration presented new results this week about the shifting nature of neutrinos<\/strong>, a subatomic particle<\/strong>, at the\u00a0Neutrino 2024 conference in Milan, Italy<\/a>. Ole Miss professors and students\u00a0have been a part of Fermilab’s operations, part of the U.S. Department of Energy, for more than a decade<\/a>.<\/p>\n\n\n\n “Our conclusions present the scientific community with the most precise measurement of its kind, putting us close to understanding one of our universe’s greatest mysteries,” said Luiz R. Prais<\/strong>, a third-year doctoral candidate in high-energy physics from Palmares Paulista, Brazil.<\/p>\n\n\n\n Prais and Andrew Dye<\/strong>, a fifth-year doctoral candidate in the same field from Richmond Hill, Georgia, are both students in professor Gavin Davies<\/strong>‘ neutrino physics research group. Prais and Dye presented their findings Wednesday (June 19) at the conference.<\/p>\n\n\n\n “I am honored to be part of the leading analyzers behind this result, and could not be grateful enough to Dr. Davies for the mentoring during my Ph.D. project as I now approach the completion of my degree and get ready for the next step towards pushing the boundaries of human knowledge,” Prais said.<\/p>\n\n\n\n The neutrino, commonly called the\u00a0“ghost particle<\/strong>,”<\/a>\u00a0is about\u00a01,000 times smaller than an electron<\/a>\u00a0and <\/a>nearly weightless, but it acts in mysterious ways. Three kinds, or “flavors,” of neutrinos exist\u2014electron,\u00a0muon, and tau\u2014but no neutrino keeps its flavor for long.<\/p>\n\n\n\n Instead, neutrinos shift their flavor often, a process called oscillation. NOvA’s most recent data suggests that researchers have found the most common pattern for a neutrino’s change. Groupings of three neutrinos are more than 87% more likely to arrange into two light flavors and one heavy one, according to the data.<\/p>\n\n\n\n To study this change, scientists at Fermilab began sending a beam of neutrinos 500 miles from Fermilab’s National Accelerator Laboratory outside of Chicago<\/strong> to a 14,000-ton detector in Minnesota<\/strong>. The experiment began in 2014 and will continue through 2027. The NOvA<\/strong> collaboration includes more than 200 scientists from 50 institutions and eight nations.<\/p>\n\n\n\n “Being a primary contributor to these latest results from the NOvA collaboration has been an honor and a privilege,” Dye said. “These latest measurements on the larger of the two mass splittings have brought the field a significant step closer in solving the neutrino mass ordering puzzle.<\/p>\n\n\n\n “It’s the goal of any academic to contribute something meaningful to their respective fields, and being afforded the opportunity to contribute to something as significant as this is incredible, especially as a graduate student.”<\/p>\n\n\n\n Scientists do not know any practical application for neutrinos but hope that the particle’s behavior can help them understand complex subjects such as black holes, antimatter, and dark matter. Despite the new data, the reason behind the neutrino’s oscillations remains unclear, and more research is needed to better understand the elusive “ghost particle.”<\/p>\n\n\n\n![\"\"](\"https:\/\/i0.wp.com\/www.thelocalvoice.net\/oxford\/wp-content\/uploads\/2024\/06\/LuizPrais-AndrewDye-Milan-Neutrino2024.jpg?resize=640%2C853\")
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