Long-sought laser? Standard microchips may gain speedy optical connections.Even with fast personal computers, Internet goodies such as videos and podcasts often download at sluggish speeds. Now, an advance in laser technology promises to eliminate those and other nagging computer delays, its developers say. Engineers have long known how to wipe out such delays: Outfit ordinary computers with circuitry that sends and receives data as modulations of light rather than as electricity. Optical connections--those used for long-distance telecommunications, for instance--carry far more data than the metal wires that form short-range connections between computers, circuit boards, and chips do. Yet no one has built from ordinary silicon all the light-processing, or photonic, components needed to make cheap optical links for short-range uses. In recent years, engineers have begun to develop some key silicon photonic devices (SN: 10/30/04, p. 2 75). Although researchers have invented silicon lasers, they can't run on electrical power and so require an external laser for energy (SN: 3/19/05, p. 189). A new type of laser has now cleared that hurdle, its inventors claim. The laser was unveiled at a Sept. 18 press conference by a team at the University of California, Santa Barbara History The predecessor to UCSB, Santa Barbara State College, focused on teacher training, industrial arts, home economics, and foreign languages. Intense lobbying by an interest group in the City of Santa Barbara led by Thomas Storke and Pearl Chase persuaded the State and Intel Corp. of Santa Clara Santa Clara, city, Cuba Santa Clara (sän`tä klä`rä), city (1994 est. pop. 217,000), capital of Villa Clara prov., central Cuba. , Calif. (Intel is the title sponsor of some of the educational programs of Science Service, publisher of Science News.) Although not made exclusively of silicon, the device runs on electricity and could be mass manufactured in the same factories as silicon microchips are, the researchers say. "Perhaps most important is its potential to be realized on a silicon photonics See integrated optics. chip at low cost," comments opto-electronics engineer Graham T. Reed of the University of Surrey The University of Surrey is a public university in Guildford, England. It received its charter on 9 September 1966, and was situated near Battersea Park in south-west London. The institution was known as Battersea College of Technology before gaining university status. in England. Typically, manufacturers create microchip lasers from exotic--and expensive--semiconductor compounds such as 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. or 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 . Such compounds readily convert electricity to light, whereas silicon tends to generate heat. On the other hand, silicon performs exceptionally well as a conductor of light at the infrared wavelengths used for telecommunications, says Mario J. Paniccia, head of Intel's group on the invention team. Tapping the strengths of both kinds of semiconductors, the researchers etched a silicon wafer to create horizontal, rodlike, light-conducting structures, called wave-guides. Then, at a temperature low enough to be compatible with silicon-microchip processing, they bonded atop that wafer a matching wafer composed primarily of indium phosphide, explains John E. Bowers, who led the Santa Barbara Santa Barbara (săn'tə bär`brə, –bərə), city (1990 pop. 85,571), seat of Santa Barbara co., S Calif., on the Pacific Ocean; inc. 1850. engineering group. Next, the team cut up the wafers to yield laser chips in which an applied voltage makes the indium phosphide layer produce light. In each laser--less than a millimeter long and about a thousandth of a millimeter wide--the light then bounces between the indium phosphide layer and silicon waveguide waveguide, device that controls the propagation of an electromagnetic wave so that the wave is forced to follow a path defined by the physical structure of the guide. beneath it, intensifying until it shoots out the end of the waveguide as a laser beam. Such a beam could potentially carry hundreds of times as much information as an electronic signal does. A report of the research appears in the Oct. 2 Optics Express. The new hybrid design combines "the best of both worlds," comments laser engineer Alan E. Willner of the University of Southern California The U.S. News & World Report ranked USC 27th among all universities in the United States in its 2008 ranking of "America's Best Colleges", also designating it as one of the "most selective universities" for admitting 8,634 of the almost 34,000 who applied for freshman admission in Los Angeles. Stay tuned, advises physicist Richard A. Soref of the Air Force Research Laboratory at Hanscom Air Force Base Hanscom Air Force Base, initially and briefly designated Bedford Army Air Base, is a U.S. Air Force facility in Bedford, Massachusetts. It is the headquarters of the Electronic Systems Center (ESC), one of the product centers of the Air Force Materiel Command (AFMC). in Massachusetts. He notes that the quest for an electrically powered, ail-silicon laser is still going strong. |
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