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Excelitas Technologies Corp. - X-Cite Vitae LB 11/24

Pulses Shaped at Fs Frequency

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WEST LAFAYETTE, Ind., Aug. 1, 2007 -- Engineers have finely controlled the spectral properties of ultrafast light pulses, a step toward creating advanced sensors, more powerful communications technologies and more precise laboratory instruments.

The laser pulses could be likened to strobes used in high-speed photography to freeze fast-moving objects such as bullets or flying insects. These laser pulses, however, are millions of times faster than such strobes, with flashes lasting a trillionth or quadrillionth of a second -- a picosecond or femtosecond (fs), respectively.
PurdueMcKinney.jpg
Jason McKinney, a former visiting assistant professor in Purdue University's School of Electrical and Computer Engineering, works with equipment that produces pulsing laser light in the university's Ultrafast Optics and Optical Fiber Communications Laboratory. Researchers in the lab recently have shown how to finely control the spectral properties of ultrafast light pulses, a step toward creating advanced sensors, more powerful communications technologies and more precise laboratory instruments. McKinney is now an engineer at the Naval Research Laboratory. (Purdue Engineering Communications Office photo/Vincent Walter)
The properties of the pulses, when represented on a graph, take on specific shapes that characterize the changing light intensity from the beginning to end of each pulse. Precisely controlling this intensity, which is called "pulse shaping," will enable researchers to tune the laser pulses to suit specific applications, said Andrew Weiner, a professor of electrical and computer engineering at Purdue University.

Researchers at other institutions have developed ultrafast lasers producing trains of pulses that are split into hundreds of thousands of segments, with each segment representing a different portion of the spectrum making up a pulse. The segments are called "comb lines" because they resemble teeth on a comb when represented on a graph, and the entire pulse train is called a "femtosecond frequency comb." The 2005 Nobel Prize in physics was awarded to researchers who precisely controlled the frequencies of these comb lines and demonstrated applications related to advanced optical clocks, which could improve communications, enhance navigation systems and enable new experiments to test physics theory, among other possible uses.

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In the new research, based at Purdue's Ultrafast Optics and Optical Fiber Communications Laboratory, the engineers precisely "shaped" 100 comb lines from such a frequency comb in a single pulse.

"There are still huge technological challenges ahead, but we really see 100 comb lines as a milestone, a significant step," Weiner said. 

The pulse-shaping technique, called "optical arbitrary waveform generation," is not new. However, the Purdue team is the first to accomplish shaping of light pulses from a fs frequency comb and to demonstrate the technique on such a fine scale by controlling the properties of 100 spectral comb lines within each pulse.

By precisely controlling this "fine frequency structure" of laser pulses, researchers hope to create advanced optical sensors that detect and measure hazardous materials or pollutants, ultrasensitive spectroscopy for laboratory research, and optics-based communications systems that transmit greater volumes of information with better quality while increasing the bandwidth. However, fully realizing these goals will require controlling 100,000 to 1 million comb lines in each pulse, Weiner said.

The advancement enables the researchers to control the amplitude and "phase" of individual comb lines, or the high and low points of each spectral line, representing a step toward applying the technique for advanced technologies.

The findings are detailed in a paper appearing online this week in the journal Nature Photonics written by postdoctoral research associate Zhi Jiang, doctoral student Chen-Bin Huang, senior research scientist Daniel E. Leaird and Weiner, all in the School of Electrical and Computer Engineering.

The research is funded by the National Science Foundation and DARPA.

For more information, visit: http://news.uns.purdue.edu

Published: August 2007
Glossary
bandwidth
The range of frequencies over which a particular instrument is designed to function within specified limits. See also fiber bandwidth.
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 fiber
Optical fiber is a thin, flexible, transparent strand or filament made of glass or plastic used for transmitting light signals over long distances with minimal loss of signal quality. It serves as a medium for conveying information in the form of light pulses, typically in the realm of telecommunications, networking, and data transmission. The core of an optical fiber is the central region through which light travels. It is surrounded by a cladding layer that has a lower refractive index than...
phase
In optics and photonics, "phase" refers to a property of electromagnetic waves, such as light, that describes the position of a wave at a given point in time within its oscillation cycle. More specifically, it indicates the position of a wave relative to a reference point, typically the starting point of a cycle. When discussing phase in optics, it's often described in terms of the phase difference between two waves or the phase of a single wave. The phase difference between two waves is the...
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...
spectral
Pertaining to or as a function of wavelength. Spectral quantities are evaluated at a single wavelength.
waveform
A waveform is a graphical representation of the shape and magnitude of a signal over time. It typically depicts how the amplitude (strength) of the signal changes over time, with time plotted along the horizontal axis and amplitude plotted along the vertical axis. Waveforms are commonly used in fields such as electronics, physics, and signal processing to analyze and interpret various types of signals, including electrical signals, sound waves, and radio waves. The shape of a waveform provides...
bandwidthBiophotonicscomb linesCommunicationsfiber opticslaser pulsenanoNews & Featuresoptical arbitrary waveform generationoptical fiberoptical sensorsOpticsphasephotographyphotonicspulsePurdueSensors & Detectorsspectralspectroscopyultrafast laserswaveform

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