Elusive neutrinos morph on Earth, as in space. (Identity Check).For nearly half a century, physicists have scanned nuclear reactors' radiation for evidence that the wispy wisp n. 1. A small bunch or bundle, as of straw, hair, or grass. 2. a. One that is thin, frail, or slight. b. A thin or faint streak or fragment, as of smoke or clouds. 3. fundamental particles of antimatter antimatter: see antiparticle. antimatter Substance composed of elementary particles having the mass and electric charge of ordinary matter (such as electrons and protons) but for which the charge and related magnetic properties are opposite in sign. known as antineutrinos undergo bizarre identity transformations. Now, an international team working at an antineutrino an·ti·neu·tri·no n. pl. an·ti·neu·tri·nos The antiparticle of the neutrino. antineutrino The antiparticle that corresponds to the neutrino. Noun 1. detector in Japan reports that it has observed a particle shortfall that it attributes to this subatomic subatomic /sub·atom·ic/ (-ah-tom´ik) of or pertaining to the constituent parts of an atom. sub·a·tom·ic adj. 1. Of or relating to the constituents of the atom. 2. morphing act. By indicating a type of particle behavior not included in conventional particle physics, the new findings challenge the prevailing theory, or standard model, of that field. The results also build upon recent observations of similar transformations of neutrinos--the normal-matter counterparts of antineutrinos--emitted by the sun. Given those earlier findings, the new measurements indicate that unstable identities are characteristic of all neutrino neutrino (n  trē`nō) [Ital.,=little neutral (particle)], elementary particle with no electric charge and a very small mass emitted during the decay of certain other particles. types, many scientists say. "We are now closing in on the detailed properties of neutrinos," comments solar-neutrino researcher Arthur B. McDonald of Queen's University in Kingston, Ontario. "This is a major result." Neutrinos come in three types, or flavors--electron neutrinos, muon neutrinos, and tau neutrinos--and each of those has both matter and antimatter forms. Since the late 1950s, some theorists have predicted that as neutrinos travel long distances, they change from one flavor into another. "It's like a lion running along, morphing into a tiger, then into a leopard, and then back into a lion," says experimental team member John G. Learned of the University of Hawaii (body, education) University of Hawaii - A University spread over 10 campuses on 4 islands throughout the state. http://hawaii.edu/uhinfo.html. See also Aloha, Aloha Net. in Honolulu. In 1998, researchers reported the first solid evidence of such neutrino transfigurations "Transfigurations" is the title of an episode from the third season of . Plot The Enterprise discovers a crashed escape pod in an unexplored star system. Investigating, they find there is one critically injured passenger in the pod, and the crew brings him aboard the ship. , which are called oscillations oscillations See Cortical oscillations. . The scientists were tracking neutrinos created in Earth's atmosphere by cosmic rays hitting atoms (SN: 6/13/98, p. 374). The more recent solar-neutrino observations appeared to clinch the case for oscillations but couldn't completely dismiss concerns that poorly understood properties of the sun itself might explain the data (SN: 5/11/02, p. 301). Because antineutrinos can switch identities, just as neutrinos do, physicists also see the results as evidence of the consistency of physical laws in the universe, comments neutrino theorist S. Peter Rosen of the Department of Energy, in Germantown, Md., which partially funds the new experiment. The team, which includes Learned and 91 other physicists, is performing its experiment at a huge, underground detector known as the Kamioka Liquid Scintillator Antineutrino Detector The Kamioka Liquid Scintillator Antineutrino Detector (KamLAND) is an experiment at the Kamioka Observatory, an underground neutrino observatory near Toyama, Japan. It was built to detect electron antineutrinos. , or KamLAND. It's located near the city of Toyama. The team looks for light flashes caused by electron antineutrinos emitted by 69 distant nuclear power reactors in Japan and Korea. Suspended about a kilometer below-ground in a mine, the heart of the detector is a weather balloon big enough to hold a school bus. The balloon is filled with some 1,000 tons of liquid, radiation-activated organic chemicals. These compounds emit light, or scintillate, when struck by fast-moving electrons such as those generated during complex reactions triggered when electron antineutrinos strike protons in the detector fluid. After 145 days of observations at KamLAND, the experimenters report detecting only 63 percent of the electron antineutrinos that they had expected from calculations based on the reactors' output. Their tally indicates that the missing antineutrinos morphed into muon muon (my `ŏn), elementary particle heavier than an electron but lighter than other particles having nonzero rest mass. or tau antineutrinos en route. The team announced its results in Japan on Dec. 6. The new antineutrino findings parallel what's been seen with solar neutrinos, notes Giorgio Gratta of Stanford University, a KamLAND co-spokesman. The data indicate that oscillations are "a property of neutrinos and not of the sun," he says. |
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