 |
|
Hidden structure revealed in characteristics of transistor laser
April 06, 2006The transistor laser, invented by scientists at the University of Illinois at Urbana-Champaign, has been full of surprises. Researchers recently coaxed the device to reveal fundamental properties of the transistor, and of the transistor laser, moving it a step closer to commercialization.
As reported in the April 3 issue of the journal Applied Physics Letters, Nick Holonyak Jr., Milton Feng, and colleagues at the U. of I. explored the current-voltage relationship in a transistor laser. During stimulated emission, the laser light allowed the scientists to see into the device and study its elusive electronic structure.
"We were able to look at the transistor's operating characteristics, look inside of the transistor, and see features and behaviors that we couldn't see before," said Holonyak, a John Bardeen Chair Professor of Electrical and Computer Engineering and Physics. "The current-voltage characteristics were clearly distorted under stimulated recombination, compared to ordinary 58-year-old-transistor spontaneous recombination."
The transistor laser employs a quantum well and a resonator in the base to control electron-hole recombination and electrical gain. By blocking the laser resonator with white paste, the researchers converted the device into an ordinary transistor. Because the process is reversible, the researchers could compare collector characteristics when the device was functioning as a normal transistor and when it was functioning as a transistor laser, something that was never before possible.
"We found significant structure in the current-voltage characteristics of the transistor laser, that can be mapped in detail and related to the quantum-well carrier recombination," said Holonyak, who also is a professor in the university's Center for Advanced Study, one of the highest forms of campus recognition.
"We were also able to correlate optical measurements with electrical measurements of quantum-well properties," Holonyak said.
The transistor laser combines the functionality of both a transistor and a laser by converting electrical input signals into two output signals, one electrical and one optical. Photons for the optical signal are generated when electrons and holes recombine in the base, an intrinsic feature of transistors.
"When we weaken the strength of the photon generation process, we change the nature of the process connecting the electron and the hole, and we change their behavior in an electrical sense," Holonyak said. "When we let the device operate as a transistor laser, however, the photons streaming out let us look inside and see more of the mechanics that goes on. We see features of the transistor never revealed before."
The change in gain and laser wavelength corresponding to stimulated recombination on quantum-well transitions can be compared to operation in spontaneous recombination and used with conventional transistor charge analysis to determine some of the dynamic properties of the transistor laser.
"This transistor laser is letting us see the properties and mechanics of how fast the electrons and holes generate photons, and we can turn laser photon generation on and off," said Feng, the Holonyak Chair Professor of Electrical and Computer Engineering at Illinois. "This allows us to alter the processes and see how the speed and time factors are changing. This is the first time we could directly determine the lifetime, the speed of stimulated recombination. The transistor has now made certain laser measurements easier or more convenient."
This capability opens the door to developing transistor lasers that operate at different speeds for a variety of commercial applications, Feng said.
"Until now, we had missed something important and fundamental about the boundaries of what the photon can do, of what the electron and hole can do, and of what the semiconductor can do," Holonyak said. "We found those boundaries to be much further out than we had ever imagined, which now makes our prognosis for the transistor laser much more optimistic."
University of Illinois at Urbana-Champaign
The transistor laser employs a quantum well and a resonator in the base to control electron-hole recombination and electrical gain. By blocking the laser resonator with white paste, the researchers converted the device into an ordinary transistor. Because the process is reversible, the researchers could compare collector characteristics when the device was functioning as a normal transistor and when it was functioning as a transistor laser, something that was never before possible.
"We found significant structure in the current-voltage characteristics of the transistor laser, that can be mapped in detail and related to the quantum-well carrier recombination," said Holonyak, who also is a professor in the university's Center for Advanced Study, one of the highest forms of campus recognition.
"We were also able to correlate optical measurements with electrical measurements of quantum-well properties," Holonyak said.
The transistor laser combines the functionality of both a transistor and a laser by converting electrical input signals into two output signals, one electrical and one optical. Photons for the optical signal are generated when electrons and holes recombine in the base, an intrinsic feature of transistors.
"When we weaken the strength of the photon generation process, we change the nature of the process connecting the electron and the hole, and we change their behavior in an electrical sense," Holonyak said. "When we let the device operate as a transistor laser, however, the photons streaming out let us look inside and see more of the mechanics that goes on. We see features of the transistor never revealed before."
The change in gain and laser wavelength corresponding to stimulated recombination on quantum-well transitions can be compared to operation in spontaneous recombination and used with conventional transistor charge analysis to determine some of the dynamic properties of the transistor laser.
"This transistor laser is letting us see the properties and mechanics of how fast the electrons and holes generate photons, and we can turn laser photon generation on and off," said Feng, the Holonyak Chair Professor of Electrical and Computer Engineering at Illinois. "This allows us to alter the processes and see how the speed and time factors are changing. This is the first time we could directly determine the lifetime, the speed of stimulated recombination. The transistor has now made certain laser measurements easier or more convenient."
This capability opens the door to developing transistor lasers that operate at different speeds for a variety of commercial applications, Feng said.
"Until now, we had missed something important and fundamental about the boundaries of what the photon can do, of what the electron and hole can do, and of what the semiconductor can do," Holonyak said. "We found those boundaries to be much further out than we had ever imagined, which now makes our prognosis for the transistor laser much more optimistic."
University of Illinois at Urbana-Champaign
High-speed signal mixer demonstrates capabilities of transistor laser
Scientists at the University of Illinois have successfully demonstrated a microwave signal mixer made from a tunnel-junction transistor laser. Development of the device brings researchers a big step closer to higher speed electronics and higher performance electrical and optical integrated circuits.
Transistor laser functions as non-linear electronic switch, processor
The transistor laser invented by scientists at the University of Illinois at Urbana-Champaign has now been found to possess fundamental non-linear characteristics that are new to a transistor and permit its use as a dual-input, dual-output, high-frequency signal processor.
More Transistor Laser Current Events and Transistor Laser News Articles
|
QUANTUM ELECTRONICS The Fundamentals of Transistors and Lasers by John Pierce (Author) | |
|
Quantum Electronics - The Fundamentals of Transistors and Lasers by John R. Pierce (Author) | |
 |
Organic Field-Effect Transistors (Optical Science and Engineering Series) by Zhenan Bao (Editor), Jason Locklin (Editor) The remarkable development of organic thin film transistors (OTFTs) has led to their emerging use in active matrix flat-panel displays, radio frequency identification cards, and sensors. Exploring one class of OTFTs, Organic Field-Effect Transistors provides a comprehensive, multidisciplinary survey of the present theory, charge transport studies, synthetic methodology, materials characterization, and current applications of organic field-effect transistors (OFETs). Covering various aspects of OFETs, the book begins with a theoretical description of charge transport in organic semiconductors at the molecular level. It then discusses the current understanding of charge transport in single-crystal devices, small molecules and oligomers, conjugated polymer devices, and charge... |
 |
Technology of Quantum Devices by Manijeh Razeghi (Author) Technology of Quantum Devices offers a multi-disciplinary overview of solid state physics, photonics and semiconductor growth and fabrication. Readers will find up-to-date coverage of compound semiconductors, crystal growth techniques, silicon and compound semiconductor device technology, in addition to intersubband and semiconductor lasers. Recent findings in quantum tunneling transport, quantum well intersubband photodetectors (QWIP) and quantum dot photodetectors (QWDIP) are described, along with a thorough set of sample problems. |
 |
1997 Advanced Workshop on Frontiers in Electronics: Wofe '97 Proceedings : Puerto De LA Cruz, Tenerife, Spain, 6-11 January 1997 by Spain) Advanced Workshop on Frontiers in Electronics (1997 : Santa Cruz de Tenerife (Author), Gernot S. Pomrenke (Author), Gernot S. Pomrenke (Editor), Fritz Schuermeyer (Editor), Michael Shur (Editor), Jimmy Zu (Editor), Lasers and Electro-Optics Society (Editor) This text presents advances in the frontiers of electronic device and circuit research and development. It also discusses low-paper digital electronics, microwave power circuits and optoelectronics. |
|
Optoelectronic processors implemented using integrated VSCELS, FETS and detectors (AFRL-SN-RS-TR-) by Charles Wheeler (Author) | |
 |
Silicon Heterostructure Handbook: Materials, Fabrication, Devices, Circuits and Applications of SiGe and Si Strained-Layer Epitaxy by John D. Cressler (Editor) An extraordinary combination of material science, manufacturing processes, and innovative thinking spurred the development of SiGe heterojunction devices that offer a wide array of functions, unprecedented levels of performance, and low manufacturing costs. While there are many books on specific aspects of Si heterostructures, the Silicon Heterostructure Handbook: Materials, Fabrication, Devices, Circuits, and Applications of SiGe and Si Strained-Layer Epitaxy is the first book to bring all aspects together in a single source. Featuring broad, comprehensive, and in-depth discussion, this handbook distills the current state of the field in areas ranging from materials to fabrication, devices, CAD, circuits, and applications. The editor includes snapshots of the industrial... |
| © 2009 BrightSurf.com |