UCLA Claims First Silicon Laser

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11/5/2004



LOS ANGELES -- Researchers at UCLA have demonstrated the first silicon laser, which could lead to more effective biochemical detection, secure communications and defense against heat-seeking missiles.

"This development shows that despite popular belief, a laser can indeed be made on a silicon chip," said Bahram Jalali, professor of electrical engineering at the UCLA Henry Samueli School of Engineering and Applied Science, who led the research team.

"The lack of a silicon laser has been a major roadblock in the progress of silicon optoelectronics and photonics," said Jagdeep Shah, program manager of the Defense Advanced Research Projects Agency Microsystems Technology Office, which funded the research. "The demonstration of a Raman laser in silicon has the potential to lead to new military applications in communications and sensing." Shah is a fellow of the American Physical Society and the Optical Society of America.

"Demonstration of the silicon laser by UCLA researchers is a major breakthrough that can make optical wireless a reality," said Jamie Montgomery, CEO of Montgomery and Co., a California-based investment banking firm specializing in the technology sector. "This technology also has important applications in homeland security."

"Our approach uses the natural atomic vibrations of silicon to create or amplify light," Jalali said. "This is significant because no special impurity or complicated device structure is needed."

This approach, called the Raman effect, is used in optical fibers for light generation and amplification. Until the UCLA research began, it had not been considered for creating silicon optical devices, since several kilometers of fiber are required to make a useful device whereas the typical silicon chip is millimeters in size.

In the past, many researchers have attempted, without success, to create a silicon laser by introducing impurities in the material, or by using exotic and complex device structures. Even if successful, such processes render the device incompatible with standard silicon manufacturing technology. In addition, these techniques generate light only at fixed wavelengths, and often do not correspond to the optimum wavelength for most applications.

While silicon is the so-called "bread-and-butter" material of the electronic industry, said Jalali, a member of the California NanoSystems Institute, conventional wisdom contends that it cannot be used to generate light.

The UCLA researchers exploited several properties of silicon in order to successfully demonstrate their silicon laser device.

"Silicon is a crystal with a well-ordered atomic arrangement, compared to glass fiber for example, which is amorphous with a random atomic arrangement," Jalali said. "This results in a very strong Raman effect in silicon that can be exploited to create a laser on a chip."

Silicon also has a high refractive index (3.5), whereas glass has a low index (1.5), and the optical energy in silicon waveguides is tightly confined, resulting in high intensity, further enhancing the Raman effect.

According to the researchers, the silicon laser exhibits nearly ideal characteristics and is already producing pulsed radiation with a very high peak power of one watt. Pulsed operation is needed in many detection and communication systems.

"A key attribute of the new technology is that it can produce mid-infrared radiation without any cooling," Jalali said. "This is a drastic improvement over current technology, where antimonite-based material plus cryogenic conditions are required to achieve lasing."

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