The transistor invented by Milton Feng, left, and Nick Holonyak 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.
CHAMPAIGN, Ill. – 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.
“We have hit upon something surprisingly fundamental and rich in possibilities,” said Nick Holonyak Jr., a John Bardeen Chair Professor of Electrical and Computer Engineering and Physics at Illinois. “We have at once a new form of transistor and a new form of laser.”
By modifying the base region with quantum wells and resonator configurations, Holonyak, electrical and computer engineering professor Milton Feng, and their colleagues have shifted the transistor operation from spontaneous emission to stimulated emission. The altered recombination process of the transistor changes the device characteristics, giving near laser threshold a fundamental and potentially useful non-linearity. The scientists describe their work in the Feb. 6 issue of the journal Applied Physics Letters.
“Transistors have never done this before,” said Holonyak, who also is a professor in the university’s Center for Advanced Study, one of the highest forms of campus recognition. “Operating as a new form of transistor, the transistor laser offers new signal mixing and switching capabilities.”
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.
Scanning electron microscope image of a dual-input heterojunction bipolar transistor laser (HBTL) on a Cu heat sink acting as frequency mixer for up and down conversion. The image shows a cleaved, front to back, segment of the laser crystal with emitter (E), base (B), and collector (C) metallization as shown. The laser output is shown schematically as hV and the electrical output as Vout. Both output signals produce integer multiples (mixing) of the input signals at frequencies mf1 +nf2.
“Using separate base inputs, we can apply two independent signals to the active region of the transistor laser,” said Feng, the Holonyak Chair Professor of Electrical and Computer Engineering at Illinois.
“We can mix them, manipulate them, so that we get out an electrical signal which is some multiple of the first input plus some multiple of the second input,” Feng said. “We also get out an optical signal, which is modulated by some multiple of the first input plus some multiple of the second input.”
As proof of concept, the researchers demonstrated the operation of a transistor laser as a non-linear microwave mixing device and signal processor using a single emitter and a twin-contact base. Two signals, one at 2.0 gigahertz and one at 2.1 gigahertz, were mixed. Both electrical and optical output signals were obtained at mixing frequencies from 0.1 gigahertz to 8.4 gigahertz.
The data make it clear that stimulated recombination in a transistor, besides its implications for another form of laser with modulation speed potentially as high as that of a transistor, is the basis for a useful non-linear element, a different form of electronic switch and processor, the researchers said.
The transistor laser also raises the possibility of replacing wiring between components at the chip- or board-level with optical interconnects, thus offering more flexibility and capability in electronic-photonic integrated circuits.
“It’s too early to tell where all of this will go,” Holonyak said. “We’re still studying the physics and device properties of the transistor laser. We’re a long way from the end.”
Co-authors of the paper with Feng and Holonyak are postdoctoral research associates Gabriel Walter and Richard Chan, and graduate student Adam James. The Defense Advanced Research Projects Agency funded the work.
To reach Nick Holonyak, call 217-333-4149.
To reach Milton Feng, call 217-333-8080; e-mail: mfeng@uiuc.edu.
