Bucky shrink-wrap.Chemists discovered buckyballs--cage-like molecules of 60 carbon atoms--more than 20 years ago. Members of a family of carbon cages known as fullerenes, buckyballs form spontaneously in a hot gas of vaporized va·por·ize tr. & intr.v. va·por·ized, va·por·iz·ing, va·por·iz·es To convert or be converted into vapor. va carbon. But the exact mechanics of their formation have remained somewhat hazy. One theory holds that larger fullerenes form first, then shed atoms as they cool, shrinking to become buckyballs. Researchers have now filmed giant fullerenes in the act. Jianyu Huang of the Sandia National Laboratories Sandia National Laboratories, which is managed and operated by the Sandia Corporation (a wholly owned subsidiary of Lockheed Martin Corporation), is a major United States Department of Energy research and development national laboratory with two locations, one in Albuquerque, New in Albuquerque and his colleagues ran an electric current through multiwalled carbon nanotubes and filmed the results with atomic resolution using a transmission electron microscope electron microscope: see microscope. . The current heated the nanotubes to more than 2,000[degrees]C. When the high temperature broke up the innermost in·ner·most adj. 1. Situated or occurring farthest within: the innermost chamber. 2. Most intimate: one's innermost feelings. n. layer of a nanotube A carbon molecule that resembles a cylinder made out of chicken wire one to two nanometers in diameter by any number of millimeters in length. Accidentally discovered by a Japanese researcher at NEC in 1990 while making Buckyballs, they have potential use in many applications. , fullerenes appeared in its place. At first, the newly formed giant fullerenes, composed of thousands of atoms, were much larger than buckyballs. But the fullerenes, still trapped inside the heated nanotubes, kept shedding atoms, and they eventually turned into buckyballs. Huang says that this is the first time that anyone has observed such a "shrink wrap" mechanism in action. While admitting that other pathways might exist for creating the molecules, he says, "This is one way that carbon-60 can form." The team describes the results in the Oct. 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. . Huang says that refinement of the technique could allow scientists to create fullerenes of specific sizes for applications such as drug delivery and energy storage.--D. C. |
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