Glass may magnify ultrasmall-world oddities.The strange rules of quantum mechanics quantum mechanics: see quantum theory. quantum mechanics Branch of mathematical physics that deals with atomic and subatomic systems. It is concerned with phenomena that are so small-scale that they cannot be described in classical terms, and it is apply mainly to the atomic and 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. domains. Only rarely do those rules manifest themselves on a larger scale, as in the case of superconductors, which let electricity pass without resistance. Physicists prize phenomena such as these because they offer a sometimes bizarre, big-screen picture of quantum mechanics in action. Now, European researchers report that they may have discovered a thoroughly unexpected example of large-scale quantum behavior. It takes place in ultracold samples of certain types of glass. The experimenters stumbled upon it while trying to improve on low-temperature thermometers by using glasses whose capacitance, or ability to store charge, varies with temperature. The investigators expected magnetic fields magnetic fields, n.pl the spaces in which magnetic forces are detectable; created by magnetostrictive ultrasonic scalers to cause the tips of instruments such as ultrasonic scalers to vibrate. to have negligible influence on capacitance readings for the glass. To their surprise, magnetic field variations affected the measurements 10,000 times more strongly than anticipated. "These are very strange experimental results, indicating very new physics," says Christian Enss of the University of Heidelberg. The outsize out·size n. 1. An unusual size, especially a very large size. 2. A garment of unusual size. adj. also out·sized Unusually large, weighty, or extensive. response to magnetic fields starts to kick in below about 100 millikelvins (mK) and is stronger at much lower temperatures, report Enss, Peter Strehlow of the Physikalisch-Technische Bundesanstalt in Berlin, and their colleagues in the Feb. 28 PHYSICAL REVIEW LETTERS Physical Review Letters is one of the most prestigious journals in physics.[1] Since 1958, it has been published by the American Physical Society as an outgrowth of The Physical Review. . The researchers discovered that below 5.84 mK, a critical temperature at which the response intensifies, even magnetic fields a hundredth as strong as Earth's weak field alter glass capacitance. "I find this work extremely exciting," says Douglas D. Osheroff Douglas Dean Osheroff (born August 1, 1945) is an American physicist. He shared the Nobel Prize in Physics in 1996 with David Lee and Robert C. Richardson for discovering the superfluidic nature of 3He. of Stanford University. "I don't know Don't know (DK, DKed) "Don't know the trade." A Street expression used whenever one party lacks knowledge of a trade or receives conflicting instructions from the other party. if I would call this a new quantum phenomenon, but it is certainly very interesting." Working with the experimenters, some theorists have come up with an explanation for the magnetic response. They make use of an idea developed in 1972 that attributes certain properties of the glasses to the motion of particles--probably ions or ion clusters--via the quantum effect called tunneling. Chilling the glass quells heat-related jitters jitters 'Butterflies' Psychology An episode of nervousness or anxiety that often precedes a public event; jitters is a type of performance anxiety which may affect actors in a stage production–stage fright or soloist musicians; it may respond to anxiolytics of its ions enough for tunneling motions to become coordinated, the new theory proposes. The ions' synchronized movement generates a magnetic field, which interacts with external fields. Above 5.84 mK, synchronization occurs only in patches a few micrometers across. Below that temperature, the theorists say, all the sample's ions abruptly fall into the same quantum mechanical state. Similarly, atoms in a Bose-Einstein condensate (SN: 7/15/95, p. 36) and electrons in a superconductor A material that has little resistance to the flow of electricity. Traditional superconductors operate at absolute zero (-459.67 degrees Fahrenheit or -273.15 degrees Celsius). Experiments in the 1980s raised the temperature to -321 degrees Fahrenheit. share a single state. Stefan Kettemann and Peter Fulde, both of the Max Planck Institute for Complex Physical Systems in Dresden, and Strehlow described that theory in the Nov. 22, 1999 PHYSICAL REVIEW LETTERS. Although the newly reported data seem to indicate a "real effect," Anthony J. Leggett of the University of Illinois at Urbana-Champaign Early years: 1867-1880 The Morrill Act of 1862 granted each state in the United States a portion of land on which to establish a major public state university, one which could teach agriculture, mechanic arts, and military training, "without excluding other scientific argues that impurities that have intrinsic magnetism might account for it. Enss says the researchers ruled that out by determining that the glass contains too few magnetic impurities to have an appreciable effect. A skeptical Philip W. Anderson of Princeton University, who helped devise the 1972 tunneling theory, says that researchers have yet to identify what entities do the tunneling--ions, groups of ions, or something else. "What kinds of conclusions can you draw about 'a riddle, wrapped in a mystery inside an enigma'?" he asks, quoting Winston Churchill. Enss concedes that the presence of a large-scale quantum state in glass below 5.84 mK remains unproven. He and his coworkers have begun experiments to test for definitive evidence, such as interference effects between samples. "There might be other explanations [than large-scale quantum effects]," he says, "but so far there isn't one." |
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