IN SPEED OF LIGHT; BRIGHT IDEA: RESEARCHERS LOOK TO LASERS FOR FASTER, CHEAPER PCS.Byline: Jon Van Chicago Tribune Chicago Tribune Daily newspaper published in Chicago. The Tribune is one of the leading U.S. newspapers and long has been the dominant voice of the Midwest. Founded in 1847, it was bought in 1855 by six partners, including Joseph Medill (1823–99), who made the paper Three decades ago, when the computer industry was in its infancy, its undisputed leader, IBM (International Business Machines Corporation, Armonk, NY, www.ibm.com) The world's largest computer company. IBM's product lines include the S/390 mainframes (zSeries), AS/400 midrange business systems (iSeries), RS/6000 workstations and servers (pSeries), Intel-based servers (xSeries) , had a single-word motto: ``Think.'' As the 20th century winds down, and computers are ubiquitous, an appropriate update might be: ``Think Small.'' That is certainly the working slogan among Northwestern University Northwestern University, mainly at Evanston, Ill.; coeducational; chartered 1851, opened 1855 by Methodists. In 1873 it absorbed Evanston College for Ladies. researchers working to make new kinds of computer chips that can take the industry into the next century with technology that is far faster, cheaper and more powerful than anything now in sight. These chips will use components 1,000 times smaller than today's miniaturized electronic chips; and the new components will manipulate light instead of electricity to do their work. Traditional electronic computer chips, which have been doubling in power and dropping in Dropping in is a skateboarding trick with which a skateboarder can start skating a half-pipe by dropping into it from the coping instead of starting from the bottom and pumping gradually for more speed. price and size for decades, now may be approaching the physical limits within which millions more transistors can be packed into ever-smaller spaces. Many chip developers believe new approaches are needed for information technology to meet market expectations. At Northwestern, a research team is making devices that manipulate bits of light, called photons, instead of the electrons that are the basis for today's computing industry. Photons already are widely used in telecommunications to carry a million phone calls simultaneously on optical fiber, a single strand of glass as slender as a human hair. Potential benefits of photonics are so great that at least two dozen labs across the country are working in the general field of opto-electronics, said Nick Holonyak Nick Holonyak Jr. (born in Zeigler, Illinois on November 3, 1928) invented the first visible LED in 1962 while working as a consulting scientist at a General Electric Company laboratory in Syracuse, New York and has been called "the father of the light-emitting diode". , a professor of electrical engineering electrical engineering: see engineering. electrical engineering Branch of engineering concerned with the practical applications of electricity in all its forms, including those of electronics. and physics at the University of Illinois at Urbana-Champaign Early years: 1867-1880 The Morrill Act of 1862 granted each state in the United States a portion of land on which to establish a major public state university, one which could teach agriculture, mechanic arts, and military training, "without excluding other scientific who invented the light-emitting diode. ``New labs are popping up like mushrooms,'' Holonyak said. ``This is very hot.'' Using light to boost the efficiency of electronics is beguiling, but after 35 years in the field, Holonyak is pessimistic about any overnight breakthroughs. ``It's a nice idea,'' he said, ``but a real dog to pull off. There are lots of technical problems to overcome.'' Instead of radical new advances, Holonyak expects a trickle of very useful niche applications to flow from the flurry of research into photonics now under way. In Evanston, Ill., Northwestern researchers have produced photon-manipulating devices with the potential to boost the information-carrying capacity of today's fiber by a factor of 100 to 1,000. Under the direction of Seng-Tiong Ho, a member of the electrical engineering and computer science faculty, they have created the world's tiniest laser and more recently have produced a resonator resonator /res·o·na·tor/ (rez´o-na?ter) 1. an instrument used to intensify sounds. 2. an electric circuit in which oscillations of a certain frequency are set up by oscillations of the same frequency in another or switch to go with it. This is the world of nano (1) Billionth (10 to the -9th power). See space/time. (2) Refers to the nanotech industry in general. See nanotechnology. (3) See iPod nano. - for nanometer, or billionth of a meter - instead of today's world of micro, for micrometer micrometer (mīkrŏm`ətər, mī`krōmē'tər). 1 Instrument used for measuring extremely small distances. , or millionth of a meter. These achievements have attracted attention from outside investors who have formed a company with Ho to finance the world's first laboratory dedicated to producing photonic Dealing with light (photons). See photon and photonics. devices on the scale of billionths of a meter. Obtaining investments from venture capitalists Venture Capitalist An investor who provides capital to either start-up ventures or support small companies who wish to expand but do not have access to public funding. Notes: Venture capitalists usually expect higher returns for the additional risks taken. for what amounts to basic scientific research is rare. ``These people contacted us after reading that Professor Ho had created the world's smallest laser,'' said Ira Uslander, director of industry relations at Northwestern's McCormick School of Engineering and Applied Sciences School of Engineering and Applied Science is the name of several engineering schools at universities in the United States.
``They've formed a start-up company start-up company A new business. that has raised money and fully intends to make a profit. They've placed no restrictions on Professor Ho's ability to publish his scientific findings, providing we get it patented first.'' One reason for the unusual commercial interest in basic research is industry's need for some breakthrough technology to keep its frenetic fre·net·ic or phre·net·ic also fre·net·i·cal or phre·net·i·cal adj. Wildly excited or active; frantic; frenzied. [Middle English frenetik, from Old French frenetique pace of productivity running. Ho is working at the outer limits of technology. He blends materials and uses the latest techniques for etching etching, the art of engraving with acid on metal; also the print taken from the metal plate so engraved. In hard-ground etching the plate, usually of copper or zinc, is given a thin coating or ground of acid-resistant resin. and buffing them to produce pathways for light that actually squeeze photons into a single dimension. At their smallest scale, photons are both particles and waves at the same time, and when they are forced into spaces where there is little room to move up, down or sideways, the bits of light react in ways altogether different than they do in larger surroundings and bigger groupings. Physicists refer to these changes as quantum effects, and studying these effects is the realm of Ho's science. The world's smallest laser illustrates one of these quantum effects. Lasers are streams of light that have been concentrated into a coherent beam of a single color, or wavelength. In our human-size world, where trillions times trillions of photons have plenty of room to bounce around, only one out of 10,000 to 100,000 photons available may be recruited for a laser beam. In the world's smallest laser, where small groupings of photons are jammed into spaces comparable to a subway car at 5 p.m., as many as seven of 10 available photons may be recruited for the laser beam, a mind-boggling leap in efficiency. ``People didn't expect such a jump in efficiency,'' Ho said. ``They thought the gain would be so small from a tiny laser that it wouldn't be worth making one.'' Ho's latest development is a resonator, which is a small, circular photon racetrack that can be placed adjacent to a strand of fiber with a tiny opening or gap that allows certain colors of light to enter when the gap is open. The gap opens and closes as light or electricity is applied to the resonator. This gives Ho a switch that grabs photons and sends them in a new direction at will. Such devices are available commercially today and used in telecommunications systems. But their size is measured in microns instead of in nanometers. Today's photon circuits are relatively large and simple, and may pack together four to 10 devices to manipulate photons and cost $10,000, Ho said. His goal is a chip with 1,000 super-tiny components packed together that would use far less power than today's circuits and cost far less as well. ``With today's technology, you can only afford to use photon circuits in central locations,'' Ho said. ``When you get out in the network near where the users are, you have to switch from photonics to electronics because of the costs. We want to change that, to make it cheap to move the photonics deeper into the network.'' CAPTION(S): Photo Photo: (Color) Associate Professor Seng-Tiong Ho oversees a photonic-computer chip research program at Northwestern University in Evanston, Ill. Knight-Ridder Tribune Photo Service |
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