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Theory Applies to All Lasers

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NEW HAVEN, Conn., May 29, 2008 -- Unlike standard lasers, nanofabricated diffusive random lasers (DRLs) don't contain mirrors to trap light, making it hard for physicists to apply conventional laser theory and predict the wavelength and intensity of light they will emit. But now a new unifying theory is allowing scientists to better understand and predict the properties of all lasers.

“The lasers that most people are familiar with emit a narrow beam of light in a fixed direction that has a well-defined wavelength and a predictable power output -- like those in laser pointers, bar-code readers, surgical instruments and CD players,” said A. Douglas Stone, the Carl A. Morse Professor of Applied Physics at Yale University, one of the researchers who formed the theory with colleagues at the Institute of Quantum Electronics at ETH Zurich, the Swiss Federal Institute of Technology.
RandomLaser.jpg
An artist's rendering of a random laser that is pumped with incoherent light from the top and emits coherent light in random directions. (Image courtesy Robert Tandy and Science Magazine)
In these conventional lasers, the light is trapped and amplified between parallel mirrors or interfaces and bounces back and forth along one dimension. Scientists can determine what the light output will be based on the “leakiness” of the mirrors, which is usually quite small.

But DRLs, part of a new breed of lasers made possible by modern nanofabrication techniques, consist of a simple aggregate of nanoparticles and have no mirrors to trap light. These lasers were pioneered by Hui Cao, now a professor of applied physics at Yale University, and have been proposed for applications in environmental lighting (“laser paint”), medical imaging and displays. Until now, there has been no simple way for scientists to predict the wavelengths and intensities of the light emitted by DRLs.

Although, superficially, conventional lasers and DRLs appear to operate very differently, experimental results indicated many basic similarities, and scientists have searched for a unifying description that would apply to all lasers.

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The properties of a laser are determined by measuring the lasing modes, including the pattern of light intensity within the laser, and the wavelengths of light it puts out. With conventional lasers, these modes can easily be obtained through simulations.

“For random lasers, time-dependent simulations are difficult to do, hard to interpret, and don't answer the question: ‘What is the nature of the lasing modes in a random laser?’” Stone said. “Researchers really wanted a description similar to that for conventional lasers, but no one knew how to develop such a description.”

To create their unifying theory, the researchers derived a wholly new set of nonlinear equations that fit both conventional and nonconventional lasers such as the DRL or other nanostructured lasers. Based on these equations Stone, his former PhD student Hakan Tureci, now at ETH Zurich, and two other members of Stone’s research group, Li Ge and Stefan Rotter, created a detailed computer code that can predict all the important properties of any kind of laser from simple inputs. A paper on their work was published May 2 in Science; Stone is senior author.

“The state of laser theory after 40 years was an embarrassment; it was essentially qualitative, but not predictive or quantitative,” Stone said. “We went back to the basics -- and we think we have now solved that problem.”

“By developing a new theory in which the main properties of a laser can be physically understood...they have provided a substantially broader perspective of laser physics that unifies the physical description of many possible laser structures,” a “Perspective” review of the theory in the same issue of Science stated.

“Ultimately, we hope that our code can be used as a design tool for new classes of micro- and nanolasers with important applications,” said Stone, who also believes that eventually their theory will become part of the answer to the question: How does a laser work?

The research was funded by the National Science Foundation, the Max Kade and W. M. Keck foundations, and by the Aspen Center for Physics in Colorado.

For more information, visit: www.yale.edu

Published: May 2008
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.
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...
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.
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