Speed demon gets hooked on silicon.Industrial scientists have devised a way to coat wafers of silicon, the stuff of the microelectronics revolution, with a high-performance semiconductor whose wider use could be a boon to many areas of electronics. Mating silicon to gallium arsenide An alloy of gallium and arsenic compound (GaAs) that is used as the base material for chips. Several times faster than silicon, it is used in high frequency applications such as cellphones, DVD players and fiber optics. , which currently shows up in special applications, which has been a technological goal for more than 30 years. If the fabrication fabrication (fab´rikā´sh  n),n the construction or making of a restoration. advance announced this month by Motorola in Schaumburg, Ill., works on a commercial scale, fast low-power chips may become less expensive and more common, semiconductor specialists say. The same may prove true of chips hosting solid-state lasers and other optical components. Those changes could benefit consumers by shrinking the size and cost of cell phones, 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. the technique's developers. The new process may also make more affordable such technologies as collision-avoidance systems for vehicles and fiber-optic telecommunications to homes. Wafers of gallium arsenide and other semiconductors that can transmit electrons at high speeds and efficiently emit or detect light are costly and fragile. Previous efforts to graft such compounds onto a cheap, flexible silicon base failed because their crystalline structures don't align with that of silicon. In gallium arsenide, the atoms are 4 percent further apart than atoms in a silicon wafer are. Although researchers have grown gallium arsenide on silicon in the past, the resulting crimping and strain in the compound's crystal lattice crystal lattice Three-dimensional configuration of points connected by lines used to describe the orderly arrangement of atoms in a crystal. Each point represents one or more atoms in the actual crystal. made it unsuitable for optical electronic components. To get around the crystal mismatch, the Motorola researchers say they have squeezed two other materials between the silicon and gallium arsenide. Because atoms shift around in those interlayers, the gallium arsenide bonds to the intermediate layer beneath it without warping. "That's the magic of it," says Jamal Ramdani of Motorola's Physical Sciences Research Laboratories in Tempe, Ariz. After 2 years of secret development, Motorola has filed more than 270 patent applications based on the technique. Semiconductor specialists outside the company agree that successfully mating the two materials promises to be important. However, until the Motorola work appears in the scientific literature, those specialists also are greeting the announcement with caution. On Tuesday, William Ooms, a research manager at Motorola, described the technique at a materials science materials science Study of the properties of solid materials and how those properties are determined by the material's composition and structure, both macroscopic and microscopic. workshop in Chattanooga, Tenn. "If this is real, it's really important," comments Joe C. Campbell of the University of Texas in Austin. "But there have been some premature claims before." The recent advance arose from an earlier setback. Ramdani and other researchers were working toward tiny transistors free of the current leaks that plague such components (SN: 3/25/00, p. 204). In 1999, the researchers made what the company declared to be "the world's thinnest functional transistor" by growing a scanty layer of the ceramic material strontium titanate Strontium titanate is an oxide of strontium and titanium with the chemical formula SrTiO3. It is a centrosymmetric ferroelectric material with a perovskite structure. (STO) on silicon. Yet when they tried to pare that layer further, oxygen corrupted the underlying silicon, creating a spongy spongy /spon·gy/ (spun´je) of a spongelike appearance or texture. spong·y adj. Resembling a sponge in appearance, elasticity, or porosity. layer of silicon dioxide silicon dioxide: see silica. (SiO2) A hard, glassy mineral found in such materials as rock, quartz, sand and opal. In MOS chip fabrication, it is used to create the insulation layer between the metal gates of the top layer and the silicon elements below. beneath the STO. At first, Ramdani considered the new layer an obstacle. But he says that while vacationing on a beach, he realized that the layer might be a godsend god·send n. Something wanted or needed that comes or happens unexpectedly. [Alteration of Middle English goddes sand, God's message : goddes, genitive of God, God . He had noticed that it enabled the STO crystal to relax despite a 2 percent mismatch with the silicon. Ramdani began wondering whether the STO would serve the same function for gallium arsenide. Initial experiments confirmed his hunch. In the 2 years since, the roughly 100 researchers assigned to the project have surmounted sur·mount tr.v. sur·mount·ed, sur·mount·ing, sur·mounts 1. To overcome (an obstacle, for example); conquer. 2. To ascend to the top of; climb. 3. a. To place something above; top. many hurdles, including getting gallium arsenide to bond to the entire surface of an underlying layer of STO. These investigators have also made working cell-phone amplifiers and an infrared-light-emitting device using the new wafers. What's more, they've made wafers with 300-millimeter diameters--twice that of the largest wafers of gallium arsenide alone. The amplifiers will hit the market within months, the company predicts. The gallium arsenide feat may be just a beginning. Different interlayers should allow other semiconductors, such as indium phosphide phosphide Any of a class of chemical compounds in which phosphorous is combined with a metal. Phosphides exhibit a wide variety of chemical and physical properties. Phosphides that are rich in metal have high melting points and are hard, brittle, and chemically inert; these , to grow on silicon. Whereas gallium arsenide transistors are about 10 times as fast as those of silicon, indium phosphide transistors up the pace by another factor of 10. "If they can do it with gallium arsenide, they can do it with other materials," surmises Vincent P. LaBella of the University of Arkansas The University of Arkansas strives to be known as a "nationally competitive, student-centered research university serving Arkansas and the world." The school recently completed its "Campaign for the 21st Century," in which the university raised more than $1 billion for the school, used in Fayetteville. |
|
||||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion