Lighthearted transistor: electronic workhorse moonlights as laser.Transistors have long served as the building blocks of microelectronics. More recently, microchip lasers have been emerging as cornerstones of light-based circuitry, or photonics. Now, engineers have melded the two types of components into one miniature device that both amplifies electric current and emits a narrow beam of single-wavelength light. "It's simultaneously a transistor and a laser. It's a transistor laser,' says co-developer 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". Jr. of 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 . He previously contributed to the invention of various optoelectronics gadgets, including the first practical light-emitting diode, or LED. The transistor laser is "a major technology breakthrough in high-speed optoelectronics," comments K.C. Wang of HR Laboratories in Malibu, Calif. The novel hybrid opens the way to significant speedups of computer circuits and telecommunication channels, its developers say. For instance, it may boost the rate at which light signals in an optical fiber can be turned on and off to represent digital 1s and 0s. By easing integration of electronic and photonic elements, the new device may also bring about enhanced performance of consumer products and industrial equipment. Holonyak and his colleagues Milton Feng Milton Feng co-created the first transistor laser, working with Nick Holonyak in 2004. The paper discussing their work was voted in 2006 as one of the five most important papers published by the American Institute of Physics since its founding 75 years ago. , Gabriel Walter, and Richard Chan describe their dual-action component in the Nov. 15 Applied Physics Letters Applied Physics Letters is a weekly peer-reviewed scientific journal published by the American Institute of Physics devoted to the publication of new experimental and theoretical papers about applications of physics to science, engineering, and modern technology. . Although the team currently must chili its microdevice to -73 [degrees]C to achieve laser action, "we believe we'll be [using the device] at room temperature very soon, Feng says. In creating the new transistor laser, Holonyak builds upon a finding that he and his colleagues published in January (SN: l/10/04,p.21). They revealed then that a type of superfast, high-current transistor known as a heterojunction bipolar transistor The heterojunction bipolar transistor (HBT) is an improvement of the bipolar junction transistor (BJT) that can handle signals of very high frequencies up to several hundred GHz. It is common in modern ultrafast circuits, mostly radio-frequency (RF) systems. can emit useful amounts of infrared light Noun 1. infrared light - electromagnetic radiation with wavelengths longer than visible light but shorter than radio waves infrared emission, infrared radiation, infrared . Such a transistor consists of layers of exotic 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. , stacked on a microchip. To make a transistor that pumps out even more infrared light, the team inserted an extra set of layers into the stack, Feng explains. Those extra layers, known as a quantum well A quantum well is a potential well that confines particles, which were originally free to move in three dimensions, to two dimensions, forcing them to occupy a planar region. , promote pooling of positive charges--which are actually vacancies within the electron clouds that surround atoms. As electrons from the current flowing through the transistor spill into those vacancies, the positive charges vanish in flashes of light. Other upper and lower sets of added layers confine the light and channel it to the stack's reflective edges. The edges bounce the waves back and forth, prompting even more light emission, which builds up to a laser beam. |
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