Researchers predict, then produce superior titanium alloys. (Invent by Number).Ingenious people have produced alloys since ancient times. By trial and error, they mixed metals and other elements until the whole came out better than any component alone. In recent years, some scientists have said that alloy development is a mature field with little room for improvement. This week, however, researchers report a new method for making titanium-based alloys with many qualities far superior to those in any alloy previously known. The team originally intended to develop materials for automobile parts, says Takashi Saito of Toyota Central Research and Development Laboratories in Nagakute, Japan. Instead, he and his coworkers wound up with materials that Saito says are too expensive for mass production in automobiles but have unusual properties suitable for a new generation of precision screws, eyeglass eye·glass n. 1. eyeglasses Glasses for the eyes. 2. A single lens in a pair of glasses; a monocle. 3. See eyepiece. 4. See eyecup. frames, medical devices, sporting goods Noun 1. sporting goods - sports equipment sold as a commodity commodity, trade good, good - articles of commerce sports equipment - equipment needed to participate in a particular sport , and spacecraft parts. The alloys are strong yet unusually elastic, so they can deform more than other alloys and still return to their original shape. Engineers can also readily mold or bend the materials at room temperature into various shapes, a property called superplasticity Superplasticity The unusual ability of some metals and alloys to elongate uniformly thousands of percent at elevated temperatures, much like hot polymers or glasses. . The materials also possess two characteristics desirable in machine parts that experience wild fluctuations in temperature, such as those in a spacecraft. While most metals expand with any rise in temperature, the new alloys expand very little between -200[degrees]C and 300[degrees]C. Moreover, conventional alloys deform different amounts at different temperatures, but the new materials show about the same deformation whether it's -200[degrees]C or 300[degrees]C. Saito and his coworkers report in the April 18 Science that they devised calculations with which they can predict what combination of elements would make an alloy with these properties. The researchers determined that a desirable titanium-based alloy must meet three criteria, which they call "magic numbers Magic numbers The number of neutrons or protons in nuclei which are required to fill major quantum shells. They occur at particle numbers 2, 8, 20, 50, and 82. " that are based on quantum mechanical calculations reflecting the behavior and arrangement of atoms and electrons. The scientists add that an alloy meeting the criteria must be cold worked, or deformed de·formed adj. Distorted in form. by compression at room temperature, before it shows the extraordinary properties. So far, Saito and his colleagues have made several titanium-based alloys that fit these criteria and possess the desired properties. The materials all include oxygen, and one, for example, also contains niobium niobium (nīō`bēəm), metallic chemical element; symbol Nb; at. no. 41; at. wt. 92.9064; m.p. about 2,468°C;; b.p. 4,742°C;; sp. gr. 8.57 at 20°C;; valence +2, +3, +4, or +5. , tantalum tantalum (tăn`tələm) [from Tantalus], metallic chemical element; symbol Ta; at. no. 73; at. wt. 180.9479; m.p. 2,996°C;; b.p. 5,400±100°C;; sp. gr. 16.65 at 20°C;; valence +2, +3, +4, or +5. , and zirconium zirconium (zərkō`nēəm), metallic chemical element; symbol Zr; at. no. 40; at. wt. 91.22; m.p. about 1,852°C;; b.p. 4,377°C;; sp. gr. 6.5 at 20°C;; valence +2, +3, or +4. . The new alloys' properties are "remarkable," says Gary Shiflet of the University of Virginia in Charlottesville. In particular, he says, their superplasticity could eliminate the need for expensive machining techniques when shaping titanium alloys Titanium alloys are metallic materials which contain a mixture of titanium and other chemical elements. Such alloys have very high tensile strength and toughness (even at extreme temperatures), light weight, extraordinary corrosion resistance, and ability to withstand extreme into products. Perhaps more importantly, says Shiflet, the new report demonstrates the power of a computational method to predict alloys that never would have been made through trial and error. Now, Shiflet asks whether the magic-numbers approach applies to other important classes of alloys, such as the nickel-based ones. "We will try it soon," says Saito. |
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