Cool wire: nanostructure boosts superconductor.Superconductive wire remains a wannabe technology for many applications. Although some ceramic wires can compete with conventional copper for use in power lines, they don't meet requirements for widespread use in industrial devices containing wire coils, such as transformers and motors. Now, a ceramic-wire prototype has performed so well in 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;. tests that it could win against copper across the gamut of expected uses, its inventors claim. Whether the wire could be made abundantly and cheaply remains uncertain. Pin-length strips of the wire, a narrow, layered ribbon including a nickel-alloy base and a superconductive ceramic film, attained record currents in magnetic fields magnetic fields, n.pl the spaces in which magnetic forces are detectable; created by magnetostrictive ultrasonic scalers to cause the tips of instruments such as ultrasonic scalers to vibrate. like those in coils, report researchers at Oak Ridge (Tenn.) National Laboratory. "This is a first demonstration that, in a single superconducting wire, you can have such performance" says Amit Goyal. Goyal and his colleagues describe the new wire in the March 31 Science. "We think this is a very important result. It's a world-record result," comments Alexis P. Malozemoff of the wire-manufacturing company American Superconductor in Westhorough, Mass. It's a "proof of principle" but not an advance that could be incorporated directly into American Superconductor's manufacturing approach, Malozemoff adds. On the other hand, Goyal says, companies in Japan and Germany are pursuing a wire-making process compatible with the Oak Ridge advance. Since the early 1990s, many researchers have made wires from ceramic materials, known as high-temperature superconductors, that carry electricity without resistance . (SN: 11/30/02,p. 350). Although the materials superconduct only at less than about 135 kelvins, that's balmy compared with the temperatures near absolute zero required by some other superconductors. American Superconductor and other companies already produce such a wire, but it contains silver, making it pricey. Furthermore, it's superconductive in high magnetic fields High magnetic fields Magnetic fields that are large enough to significantly alter the properties of objects that are placed in them. Valuable research is conducted at high magnetic fields. only when it's cooled to about 30 K. A magnetic field tends to disrupt superconductivity when eddies of electric current created by the magnetic field move along with the main current. In wires such as the Oak Ridge prototype, structural irregularities in the ceramic coating ceramic coating, n a thin layer of ceramic material, commonly hydroxyapatite, used to cover dental implants. This typically increases the hardness of the implant and can also make the implant bond more readily with bone. can preserve superconductivity by holding the eddies in place. Using a laser in a vacuum, the Oak Ridge team 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 a mixture of powders of the superconductive compound yttrium barium copper oxide Yttrium barium copper oxide, often abbreviated YBCO, is a chemical compound with the formula YBa2Cu3O7. This material, a famous "high-temperature superconductor", achieved prominence because it was the first material to achieve superconductivity (YBCO YBCO Yttrium Barium Copper Oxide YBCO Yttrium Barium Cuprate ) and of barium zirconate, which doesn't superconduct. As the vapor condensed con·dense v. con·densed, con·dens·ing, con·dens·es v.tr. 1. To reduce the volume or compass of. 2. To make more concise; abridge or shorten. 3. Physics a. on the ribbon, it formed a film of YBCO containing nanometer-scale disks of barium zirconate. The Oak Ridge team reports that the barium zireonate disks stack up in orderly columns that span the film. The wires' exceptional performance stems from how well such columns pin down the eddies, the group concludes. Stephen R. Foltyn of the Los Alamos (N.M.) National Laboratory says that the Oak Ridge samples performance is similar to that of the wires that he and his colleagues previously made of YBCO with randomly scattered barium zirconate particles. David C. Larbalestier of the University of Wisconsin-Madison “University of Wisconsin” redirects here. For other uses, see University of Wisconsin (disambiguation). A public, land-grant institution, UW-Madison offers a wide spectrum of liberal arts studies, professional programs, and student activities. says that the Oak Ridge wire is an advance because its superconducting layer is thicker than that of earlier prototypes. Although he doubts that the vaporization vaporization, change of a liquid or solid substance to a gas or vapor. There is fundamentally no difference between the terms gas and vapor, but gas is used commonly to describe a substance that appears in the gaseous state under standard conditions of method is compatible with manufacturing, he says, "the new result ... shows the technology has real legs." |
|
||||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion