Carbon nanotubes could shrink machines. (X Rays to Go).Carbon nanotubes See nanotube. have been the darlings of the technology community for a decade. Researchers around the word have been touting them as promising components for making products ranging from microchips to medicines. Now, these tiny tubes have found their way into a novel X-ray machine Noun 1. X-ray machine - an apparatus that provides a source of X rays apparatus, setup - equipment designed to serve a specific function fluoroscope, roentgenoscope - an X-ray machine that combines an X-ray source and a fluorescent screen to enable direct that could improve examinations of patients in the hospital, victims at the scene of an automobile crash, or luggage at airport-security checkpoints. Unlike conventional machines, the new one doesn't require high temperatures to generate high-energy electrons for producing X rays. A thin layer of carbon nanotubes operating at room temperature does the job, says developer Otto Zhou of the University of North Carolina at Chapel Hill The University of North Carolina at Chapel Hill is a public, coeducational, research university located in Chapel Hill, North Carolina, United States. Also known as The University of North Carolina, Carolina, North Carolina, or simply UNC . "There's been an enormous amount of hype about what carbon nanotubes can do, and very little actually has happened in terms of this kind of application," comments Walter de Heer of the Georgia Institute of Technology Georgia Institute of Technology, in Atlanta, Ga.; coeducational; state supported; chartered 1885, opened 1888. It is a member school in the university system of Georgia. Significant among its facilities and programs are the Frank H. in Atlanta. The X-ray method is "an application whose time has come," he says. A conventional X-ray machine generates electrons by heating metal filaments inside a vacuum chamber to temperatures as high as 2,000[degrees]C. When those electrons hit another piece of metal, they produce X rays. The prototype devised by Zhou and his colleagues uses carbon nanotubes in place of the metal filaments. When exposed, unheated, to an electric field, the nanotubes behave like tiny electron guns. Since metal filaments burn out easily at their high operating temperatures, the new devices will last longer, Zhou says. They should also save energy and time. Moreover, because the prototype operates at room temperature, researchers will be able to develop very small machines for portable X-ray work, such as in an ambulance or airport-security and customs operations, says Zhou. He and his colleagues describe the prototype machine in the July 8 Applied Physics Letters Applied Physics Letters is a weekly peer-reviewed scientific journal published by the American Institute of Physics devoted to the publication of new experimental and theoretical papers about applications of physics to science, engineering, and modern technology. . The report includes X-ray images of a fish and of a medical model of a hand containing human bones. "This important work ... brings carbon-nanotube X-ray sources much closer to commercializable products," comments Ray Baughman Ray Baughman received a B.S. in Physics from Carnegie Mellon University and a Ph.D. in the Materials Science area from Harvard University. Upon graduation he went to Allied Chemical, which later became AlliedSignal and Honeywell. of the University of Texas at Dallas History The university was originally started as a research arm of Texas Instruments as the Graduate Research Center of the Southwest in 1961. The institute (by then renamed the Southwest Center for Advanced Studies) which at the time was located at Southern Methodist . X-ray sources based on carbon nanotubes might even be small enough someday for use in catheters inserted into the body, he says. According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. Zhou, he and his colleagues are working with manufacturers to put the first generation of carbon-nanotube X-ray machines on the market within 2 years. A new family of technologies using similar methods might become possible. Says Baughman, "This X-ray application is one of the many exciting potential uses of carbon nanotubes as electron sources, from light-emitting flat-panel displays and high-intensity lamps to microwave generators and electrical-discharge tubes for electrical-surge protection." |
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