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Nanolaser Size Limit Broken

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TEMPE, Ariz., July 28, 2009 -- An international research collaboration is reporting advances in breaking previous limitations on how small lasers can be made. The work opens up possibilities for using nanoscale lasers to significantly improve optical communications, single molecule detection and medical imaging.

Researchers at Arizona State University and Technical University of Eindhoven, Netherlands, reported their advances in breaking the diffraction limit in a recent edition of the online science and engineering journal Optics Express. Authors of the report include professor Martin Hill, who leads the Eindhoven team, and ASU team leader Cun-Zheng Ning, a professor in the School of Electrical, Computer and Energy Engineering in ASU’s Ira A. Fulton Schools of Engineering.

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Cun-Zheng Ning in his nanophotonics laboratory at Arizona State University. (Photo © Copyright Arizona Board of Regents)

Engineers have been trying to make lasers smaller because it would enable the devices to be more effectively integrated with small electronics components. The more lasers that can be used with these components, the faster electronic devices could perform. But a problem has been the diffraction limit, a property associated with any wave, such as a beam of light. Current theory says the size of lasers in any one dimension (such as thickness) are thought to be limited to one-half of the wavelength involved.

For instance, for lasers used in optical communications the required wavelength is about 1500 nm, so a 750-nm laser was thought to be the smallest a laser could be made for that application.

In an optically denser medium such as a semiconductor, this limit is reduced by a factor of the index of refraction (expressed mathematically as ~3.0) of a semiconductor – in this case to about 250 nm.

But the research teams at ASU and Eindhoven are showing there are ways around this supposed limit. One such way is by using a combination of semiconductors and metals such as gold and silver.

“It turns out that the electrons excited in metals can help you confine a light in a laser to sizes smaller than that required by the diffraction limit,” Ning said. “Eventually, we were able to make a laser as thin as about one quarter of the wavelength or smaller, as opposed to one half.”

Ning and Hill have achieved something like that by using a “metal-semiconductor-metal sandwich structure,” in which the semiconductor is as thin as 80 nm and is sandwiched between 20-nm dielectric layers before putting metal layers on each side.

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They have demonstrated that such a semiconductor/dielectric layer, thinner than the diffraction limit and squeezed between metal layers, can actually emit laser light – a laser with the smallest thickness of any ever produced. The structure, however, has worked only in a low-temperature operating environment. The next step is to achieve the same laser light emission at room temperature.

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Researchers worldwide are interested in integrating such metallic structures with semiconductors to produce smaller nanolasers because of the promise of applications for smaller lasers in a wide range of technologies.

“This is the first time that anyone has shown that this limit to the size of nanolasers can be broken,” Ning said. “Beating this limit is significant. It opens up diverse possibilities for improving integrated communications devices, single molecule detection and medical imaging.”

Nanoscale lasers can also be integrated with other biomedical diagnostic tools, making them work faster and more efficiently, he said.

These advances also represent a major step in nanophotonics – the study of the behavior of light on the nanometer scale and the ability to fabricate devices in nanoscale.

“Nanolasers can be used for many applications, but the most exciting possibilities are for communications on a central processing unit (CPU) of a computer chip,” Ning said.

As computers get faster, the communication between different parts in a computer creates a processing bottleneck, he said.

Since a signal can be transmitted between computer components much faster by a light wave emitted by a laser than by metal wires, optical or light-based communication is “the ultimate solution for improving on semiconductor chip communications,” Ning said.

“But before this becomes a reality, lasers have to be made small enough to be integrated with small electronics components,” he says. “This is why the Department of Defense and chip manufacturers such as Intel are working on optical solutions for on-chip communications.”

Research in this field in the US is being funded by the DARPA, the central research and development organization for the US Department of Defense. The agency is supporting a collaborative team partnering researchers at ASU, the University of California at Berkeley and the University of Illinois, Urbana-Champaign.

ASU’s collaboration with Hill’s team at Eindhoven happened by coincidence, Ning said.

“We discovered we were working on the same problems and trying to achieve similar goals using similar ideas,” he said. “So the partnership developed.”

For more information on Ning's work, visit: http://nanophotonics.asu.edu

Published: July 2009
Glossary
light
Electromagnetic radiation detectable by the eye, ranging in wavelength from about 400 to 750 nm. In photonic applications light can be considered to cover the nonvisible portion of the spectrum which includes the ultraviolet and the infrared.
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
optical communications
The transmission and reception of information by optical devices and sensors.
photonics
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
refraction
The bending of oblique incident rays as they pass from a medium having one refractive index into a medium with a different refractive index.
wavelength
Electromagnetic energy is transmitted in the form of a sinusoidal wave. The wavelength is the physical distance covered by one cycle of this wave; it is inversely proportional to frequency.
Arizona State UniversitybiomedicalBiophotonicsCommunicationsCun-Zheng Ningdefensedetectiondiffraction limitEindhovengoldImaginglightMartin Hillmedical imagingnanonanolaserNews & Featuresoptical communicationsOptics ExpressphotonicsrefractionResearch & TechnologysemiconductorssilverwavelengthLasers

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