Crystal puts pressure on diamonds.Diamonds have charmed high-pressure scientists. Now, a new suitor SUITOR. One who is a party to a suit or action in court. One who is a party to an action. In its ancient sense, suitor meant one Who was bound to attend the county court, also, one who formed part of the secta. (q.v.) is pressing for affection. A synthetic crystal called moissanite has squeezed in on diamond's role as the jaws of a powerful experimental device known as a diamond anvil cell A diamond anvil cell (DAC) is a device used by physicists to exert extreme pressures on a material. It consists of two opposing cone-shaped diamonds squeezed together. The resultant high pressures — in excess of a million atmospheres — are produced when force is applied . With diamond anvils, researchers squeeze materials to extraordinarily high pressures. How substances behave under such conditions can reveal geologic processes deep within planets. Materials scientists also use these anvils to study samples under extreme conditions. Diamond's unrivaled strength and rigidity have made it well suited for the intense job. Good as they are, diamond anvils have flaws. They're small, so they can hold only minute samples. Larger anvils would require larger gems, which are scarce and expensive. Also, diamond's spectrographic spec·tro·graph n. 1. A spectroscope equipped to photograph or otherwise record spectra. 2. A spectrogram. spec signature--the wavelengths of light it absorbs and emits--interferes with the analysis of many materials. Now, a team of researchers has replaced an anvil anvil Iron block on which metal is placed for shaping, originally by hand with a hammer. The blacksmith's anvil is usually of wrought iron (sometimes of cast iron), with a smooth working surface of hardened steel. cell's diamonds with bigger crystals of moissanite, or silicon carbide silicon carbide, chemical compound, SiC, that forms extremely hard, dark, iridescent crystals that are insoluble in water and other common solvents. Widely used as an abrasive, it is marketed under such familiar trade names as Carborundum and Crystolon. . The resulting devices can squeeze much larger volumes of material, Ji-an Xu and Ho-Kwang Mao Ho-Kwang (Dave) Mao is a staff scientist at the Geophysical Laboratory of the Carnegie Institution of Washington. He is one of the most prolific users of the diamond anvil cell for research at high pressures. of the Carnegie Institution of Washington  The introduction to this article may be too long. Please help improve the introduction by moving some material from it into the body of the article according to the suggestions at (D.C.) report in the Oct. 27 SCIENCE. Within one device, the researchers recorded pressures of 52.1 gigapascals, about a half-million times atmospheric pressure atmospheric pressure or barometric pressure Force per unit area exerted by the air above the surface of the Earth. Standard sea-level pressure, by definition, equals 1 atmosphere (atm), or 29.92 in. (760 mm) of mercury, 14.70 lbs per square in., or 101. . That's high-enough pressure for many experiments whose samples are too large for current diamond anvils, says Xu. The team's largest moissanite crystal is about the size of a 300-carat diamond, he says. Most diamonds in anvils are less than 0.3 carat. Because moissanite's spectrographic signature differs from that of diamond, the new anvils enable researchers to see, for the first time, clear signatures of certain materials at high pressure, such as diamonds, says Xu. In one early example, the Carnegie researchers have used their new anvils to observe subtle details of hydrogen bonds in ice. "This anvil allows one to see a lot of new things," comments Carnegie's Russell J. Hemley, who has worked closely with Xu and Mao on other projects. Other scientists, however, caution that moissanite's applications are limited because it's not as hard as diamond. "Although moissanite is a very, very strong and very rigid material, it is still second place to diamond by a large factor," says Samuel T. Weir of the Lawrence Livermore (Calif.) National Laboratory, who uses diamond anvils. He points out that diamond anvils create pressures about 10 times those achieved in the moissanite experiments. Moissanite "is not something that's going to overtake diamond as the mainstay of high-pressure physics," he says. Still, he concludes, "for certain classes of experiments, I think it will be an important material." |
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