Can nano-sized optical antennas help LEDs replace lasers?
The advance opens the door to LEDs that can replace lasers for short-range optical communications, including optical interconnects for microchips.
“Since the invention of the laser, spontaneous light emission has been looked down upon in favor of stimulated light emission,” explained Eli Yablonovitch, an electrical engineer with Berkeley Lab’s Materials Sciences Division. “However, with the proper optical antenna, spontaneous emission can actually be faster than stimulated emission.”
Yablonovitch, who also holds a faculty appointment with the University of California (UC) Berkeley where he directs the NSF Center for Energy Efficient Electronics Science (E3S), and is a member of the Kavli Energy NanoSciences Institute at Berkeley (Kavli ENSI), led a team that used an external antenna made from gold to effectively boost the spontaneous light emission of a nanorod made from Indium Gallium Arsenide Phosphide (InGaAsP) by 115 times. This is approaching the 200-fold increase that is considered the landmark in speed difference between stimulated and spontaneous emissions. When a 200-fold increase is reached, spontaneous emission rates will exceed those of stimulated emissions.
“With optical antennas, we believe that spontaneous emission rate enhancements of better than 2,500 times are possible while still maintaining light emission efficiency greater than 50-percent,” said Yablonovitch. “Replacing wires on microchips with antenna -enhanced LEDs would allow for faster interconnectivity and greater computational power.”
The results of the study have been reported in the Proceedings of the National Academy of Sciences (PNAS) in a paper entitled ‘Optical antenna enhanced spontaneous emission’. Yablonovitch and UC Berkeley’s Ming Wu are the corresponding authors. Other authors are Michael Eggleston, Kevin Messer and Liming Zhang.
In the world of high technology lasers are ubiquitous, the reigning workhorse for high-speed optical communications. Lasers, however, have downsides for communications over short distances, i.e., one meter or less – they consume too much power and typically take up too much space. LEDs would be a much more efficient alternative but have been limited by their spontaneous emission rates.
“Spontaneous emission from molecular-sized radiators is slowed by many orders of magnitude because molecules are too small to act as their own antennas,” explained Yablonovitch. “The key to speeding up these spontaneous emissions is to couple the radiating molecule to a half-wavelength antenna. Even though we’ve had antennas in radio for 120 years, somehow we’ve overlooked antennas in optics. Sometimes the great discoveries are looking right at us and waiting.”
An arch-antenna–coupled InGaAsP nanorod, isolated by TiO2, and embedded in epoxy was used to enhance the spontaneous light emission of the InGaAsP.
Coupling a gold antenna to a InGaAsP nanorod, isolated by TiO2 and embedded in epoxy, greatly enhanced the spontaneous light emission of the InGaAsP.
For their optical antenna, Yablonovitch and his colleagues used an arch antenna configuration. The surface of a square-shaped InGaAsP nanorod was coated with a layer of titanium dioxide to provide isolation between the nanorod and a gold wire that was deposited perpendicularly over the nanorod to create the antenna. The InGaAsP semiconductor that served as the spontaneous light-emitting material is a material already in wide use for infrared laser communication and photo-detectors.
In addition to short distance communication applications, LEDs equipped with optical antennas could also find important use in photodetectors. Optical antennas could also be applied to imaging, bio-sensing and data storage applications.
Related articles and links:
www.e3s-center.org
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