Run-of-the-mill compound becomes superstar.Physicists in Japan have found superconductivity superconductivity, abnormally high electrical conductivity of certain substances. The phenomenon was discovered in 1911 by Kamerlingh Onnes, who found that the resistance of mercury dropped suddenly to zero at a temperature of about 4.2°K;. at a surprisingly high temperature in the simple, readily available metallic compound magnesium diboride. The discovery that the material can carry electric current with no resistance, reported in the March 1 NATURE by Jun Akimitsu and his coworkers at Aoyama-Gakuin University in Tokyo, has startled star·tle v. star·tled, star·tling, star·tles v.tr. 1. To cause to make a quick involuntary movement or start. 2. To alarm, frighten, or surprise suddenly. See Synonyms at frighten. scientists. Investigators worldwide are racing to measure the chemical's properties. One group has even formed the compound into tiny wires. Scientists are also testing ways of boosting the compound's so-called critical temperature; below which superconductivity kicks in. The Japanese team measured it at 39 kelvins. Researchers have long dreamed of superconductors that would operate at room temperature, or 300 K. Such substances would revolutionize industry and other sectors of society by slashing the energy required to run machines while bettering their performance. Conventional superconductors, such as certain metal alloys, are used in commercial magnetic resonance imaging magnetic resonance imaging (MRI), noninvasive diagnostic technique that uses nuclear magnetic resonance to produce cross-sectional images of organs and other internal body structures. (MRI 1. (application) MRI - Magnetic Resonance Imaging. 2. MRI - Measurement Requirements and Interface. ) machines and in research magnets. Decades of research have yielded no conventional superconductors with a critical temperature higher than 23 K. Since the late 1980s, the discovery of so-called ceramic high-temperature superconductors has diverted attention from conventional compounds. Some of the ceramic materials proved to have critical temperatures higher than 160 K, fanning hopes that room-temperature superconductivity was within reach. But it wasn't. What's more, the materials have turned out to be complex, difficult to work with, and expensive. Only now are ceramic superconductors showing up in equipment prototypes, such as power cables and motors (SN: 11/18/00, p. 330). Also, conventional theory can't explain their superconductivity. Akimitsu first described his group's findings regarding magnesium diboride on Jan. 10 at a scientific meeting in Sendai, Japan. Initially, researchers wondered if the material might be displaying a new type of superconductivity. However, mounting evidence suggests that the compound--although breaking records--obeys conventional theory. Evidence for this is described in the Feb. 26 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. by Sergey L. Bud'ko and his colleagues at Iowa State University Academics ISU is best known for its degree programs in science, engineering, and agriculture. ISU is also home of the world's first electronic digital computing device, the Atanasoff–Berry Computer. in Ames and the Department of Energy's Ames Laboratory there. The scientists, who formed magnesium diboride wires, observed the isotope effect typical of conventional superconductors. When they made magnesium diboride containing a light form, or isotope, of boron boron (bōr`ŏn) [New Gr. from borax], chemical element; symbol B; at. no. 5; at. wt. 10.81; m.p. about 2,300°C;; sublimation point about 2,550°C;; sp. gr. 2.3 at 25°C;; valence +3. , its critical temperature rose 1 K. The prospect that magnesium diboride may be the first of a line of inexpensive, easily processed superconductors with yet higher critical temperatures is fueling the excitement. Finding one such material that superconducts at 77 K, the temperature at which cooling with relatively cheap liquid nitrogen is possible, would be a huge advance, scientists say. That mark is probably still out of reach, comments Paul M. Grant of the Electric Power Research Institute in Palo Alto, Calif. He notes that theorists more than 30 years ago predicted a 40 K maximum for conventional superconductors. Nonetheless, new reports on magnesium diboride are pouring in to scientific journals and the on-line physics preprint pre·print n. Something printed and often distributed in partial or preliminary form in advance of official publication: a preprint of a scientific article. tr.v. server on the Internet (http://xxx.lanl.gov). In one preprint, Robert J. Cava and his colleagues at Princeton University describe a failed attempt to raise the compound's critical temperature by adding aluminum (http://xxx.lanl.gov/abs/cond-mat/0102262). Prospects for finding superconducting cousins of magnesium diboride remain bright, researchers say. "Never in the history of superconductivity The history of superconductivity, the property exhibited by certain substances of lacking electrical resistance at temperatures close to absolute zero, began at the end of the 19th century and culminated in Heike Kamerlingh Onnes's 1911 discovery. has there been a single, solitary example of 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. that works in a [unique] way," Cava claims. "There's always more than one." |
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