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Colorized trace of pulses from the NIST/JILA “dark pulse” laser, indicating the light output nearly shuts down about every 2.5 nanoseconds. Credit: NIST |
In an advance that sounds almost Zen, researchers at the National Institute of Standards and Technology (NIST) and JILA, a joint institute of NIST and the University of Colorado at Boulder, have demonstrated a new type of pulsed laser that excels at not producing light. The new device generates sustained streams of “dark pulses”—repeated dips in light intensity—which is the opposite of the bright bursts in a typical pulsed laser.
Despite its ominous name, the dark pulse laser is envisioned as a tool for benign communications and measurements based on infrared light frequencies. The laser’s ultrashort pulses span just 90 picoseconds (trillionths of a second), making the device suitable for measurements on short timescales. Dark pulses might be useful in signal processing because, unlike bright pulses, they generally propagate without distortion. Dark pulses might be used like a camera shutter for a continuous light beam in optical networks.
Described in Optics Express,* the new NIST/JILA technology is the first to generate dark pulses directly from a semiconductor laser cavity, without electrical or optical shaping of pulses after they are produced. The chip-sized infrared laser generates light from millions of quantum dots (qdots), nanostructured semiconductor materials grown at NIST. Quantum dot lasers are known for unusual behavior.
In the new NIST/JILA laser, small electrical currents are injected into the laser, causing the qdots to emit light. The qdots are all about the same size—about 10 nanometers (billionths of a meter) wide—and thus, because of a nanostructured design that makes them behave like individual atoms, all emit light at the same frequency. The current generates enough energy to amplify the emissions from the collective dots, creating the special properties of laser light.
The new laser depends on the qdots’ unusual energy dynamics, which have the effect of stabilizing dark pulses. After emitting light, qdots recover energy from within rapidly (in about 1 picosecond) but more slowly (in about 200 picoseconds) from energy inputs originating outside the qdots in the laser cavity. This creates a progression of overall energy gains gradually giving way to overall energy losses. Eventually, the laser reaches a steady state of repeated brief intensity dips—a drop of about 70 percent—from the continuous light background.
The dark pulse laser was developed through close collaborations between NIST experts in qdot growth and semiconductor laser design and fabrication, and JILA experts in ultrafast lasers and related measurements. NIST has ongoing research efforts to develop quantum dot lasers and to develop modeling, fabrication, and measurement methods for semiconductor nanostructures such as quantum dots. In general, semiconductor lasers are being considered for many advanced applications, such as next-generation atomic clocks based on optical frequencies, for which large lasers are costly and complex.
* M. Feng, K.L. Silverman, R.P. Mirin and S.T. Cundiff. Dark pulse laser. Optics Express. Published online June 7, 2010, as forthcoming.
Media Contact: Laura Ost, laura.ost@nist.gov, (303) 497-4880
Dear Ladies and Gentlemen,
Why do you think that dark pulses propagate without distortion? The authors do not appear to claim this in the Optics Express paper, and I doubt that the claim is true.
With best regards
Rüdiger Paschotta
Posted by: Rüdiger Paschotta | 06/23/2010 at 04:56 AM
Thanks for your comment. Our Tech Beat articles are intended for interested laypersons and need to be brief, so we often have to avoid getting in to details. We try provide readers who are interested in learning more with a link to the full paper, which we are glad you viewed.
We passed your question on to the authors, who say that a dark soliton (solitary pulse) can propagate without distortion by balancing the phenomena of dispersion and nonlinearity. While the authors do not claim that their dark pulses are dark solitons, a dark pulse launched into an optical fiber may evolve into a dark soliton. This is similar, they say, to how an arbitrary bright pulse can evolve into a bright soliton.
Posted by: Michael Baum | 06/28/2010 at 03:30 PM
OK; so exactly what wavelength is this "dark" light? What is the potential S/N ratio of this "dark" pulse versus background ambient noise? How can intelligence be conveyed without energy? Source for this information please? Any peer review?
Posted by: Joe Leikhim | 08/27/2010 at 05:02 PM
The answer to the wavelength question is a bit complex. You probably should look at the paper. As to source, you'll note the footnote citing a paper in Optics Express, which is a journal of The Optics Society (OSA). At the time of this article, the paper was accepted but "forthcoming". The proper citation is now:
M. Feng, K.L. Silverman, R.P. Mirin and S.T. Cundiff. Dark pulse quantum dot diode laser. Optics Express. Vol. 18, No. 13. June 21, 2010 p. 13385ff
If you don't have access to it, drop me a line at michael.baum@nist.gov and I'll email you a copy of the paper.
Posted by: Michael Baum | 08/27/2010 at 05:22 PM