Microresonators could bring optical sensors, communications

August 11, 2015  

Weiner microresonators

Researchers are developing "microresonators" for miniature optical sensors and other potential applications. The technology is based on the reliable generation and control of laser pulses containing a number of equally spaced frequencies called "comb lines." This graphic depicts the optical spectrum of a "pump laser" used in the technology and an intriguing optical phenomenon called "dark pulses," which might be harnessed to precisely control the comb lines. (Birck Nanotechnology Center, Purdue University)
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WEST LAFAYETTE, Ind. — Researchers have solved a key obstacle in creating the underlying technology for miniature optical sensors to detect chemicals and biological compounds, high-precision spectroscopy, ultra-stable microwave sources, and optical communications systems that transmit greater volumes of information with better quality.

The technology is based on the reliable generation and control of laser pulses containing a number of equally spaced frequencies called "comb lines." By precisely controlling the frequency combs, including their initiation, "coherence" and spacing, researchers hope to create miniature optical devices using ring-shaped "microresonators."

A research team at Purdue University has demonstrated prototypes, and new findings are described in a paper appearing online this week in the journal Nature Photonics. The findings, together with those in another paper published in July in the journal Laser and Photonics Reviews, detail an optical phenomenon called "dark pulses" and show how to precisely control the comb generation.

Whereas conventional optical communication requires many lasers to transmit various frequencies, the new devices might require only a single light source, which is then transformed to emit light at multiple wavelengths. Such an innovation would reduce cost and make possible more compact optical systems small enough to fit on electronic chips, said Minghao Qi (pronounced Ming-how Chee), an associate professor of electrical and computer engineering.

"Say you have 40 channels. If we have 40 individual lasers, together with their individual control circuitry on a single telecommunication chip, then your cost is high. If one of the lasers goes down you have to replace the entire chip. You could achieve significant cost reduction if you were able to use just one laser to create multiple wavelengths to drive different channels," he said.

The lead author of the Nature Photonics paper is postdoctoral research associate Xiaoxiao Xue (pronounced Shau-Shau Shoo).

The microresonators accumulate optical power, and enhance an otherwise weak effect of "optical nonlinear interaction," which allows for the generation of numerous frequencies, Xue said. The ring-shaped device has a radius of about 100 micrometers, or the width of a sheet of paper, and is fabricated from silicon nitride, a material compatible with silicon material widely used for electronics. 

Researchers had previously created "bulk optics" systems, which use mirrors, lenses and other optical components arranged on a vibration-dampened table several feet long to convert and transmit the pulsed signals. However, these systems are far too large to be practical, and the Purdue researchers miniaturized the technology, creating microresonators small enough to fit on a computer chip. However, miniaturizing the apparatus poses challenges because it is difficult to retain a property of optical fiber called "anomalous dispersion," which makes the high frequency components of a pulse travel faster than the lower ones, and was previously considered necessary to generate the frequency combs.

"To achieve anomalous dispersion in silicon nitride microresonators ordinarily requires very thick film, which is susceptible to cracking and not practical to manufacture," said Andrew M. Weiner, the Scifres Family Distinguished Professor of Electrical and Computer Engineering. "Here, we show how to generate the combs without anomalous dispersion, so we potentially no longer need the thick films."

Dark pulses can be envisioned as a shutter that is normally open to allow light to pass through, but can quickly close to block the light and then open again to turn the light back on. The entire process can be as fast as 1-2 picoseconds, almost 100 times faster than the switching speed of the fastest computer microprocessor now available.

The technology could bring miniature optical sensors to detect and measure chemicals, ultra-precise spectroscopy for laboratory research, and optical communications systems that transmit greater volumes of information with better quality and at lower cost. The microresonators can work not only in the near-infrared range required for optical communications but also in visible and mid-infrared light needed for chemical and biological sensing.

"If you had a comb you could probe molecules at multiple wavelengths at once, so it's faster and provides more information about the molecule," Xue said.

 Another potential application is as an "optical clock" for computers. Clocks are needed in computers to synchronize the operation of the billions of transistors in microprocessor chips.

"Because of the miniaturization this could be applied to clock signal distribution to help improve the performance of computer chips and also for telecommunication systems," Qi said.

The technology also could be used in photonics-assisted processing of microwave signals, especially those with large bandwidth that are difficult to process using pure electronic methods.  

The authors of the Nature Photonics paper were Xue, research assistant professor Yi Xuan, doctoral students Yang Liu and Pei-Hsun Wang, graduate student Steven Chen, former doctoral student Jian Wang, senior research scientist Daniel E. Leaird, Qi, and Weiner.

Some of the work was performed at Purdue's Birck Nanotechnology Center. This work was supported in part by the National Science Foundation, the U.S. Air Force Office of Scientific Research and DARPA. 

Writer: Emil Venere, 765-494-4709, venere@purdue.edu 

Sources: Andrew Weiner, 765-494-5574, amw@purdue.edu

Minghao Qi, 765 494-3646, mqi@purdue.edu 

Related website:

Ultrafast Optics and Optical Fiber Communications Laboratory

Note to Journalists: An electronic copy of the research paper is available by contacting Nature at press@nature.com or Emil Venere, 765-494-4709, venere@purdue.edu


Mode-locked dark pulse Kerr combs in normal-dispersion microresonators  

Xiaoxiao Xue1, Yi Xuan1,2, Yang Liu1, Pei-Hsun Wang1, Steven Chen1, Jian Wang1,2, Dan E. Leaird1, Minghao Qi1,2 and Andrew M. Weiner1,2*

1School of Electrical & Computer Engineering, Purdue University

2Birck Nanotechnology Center, Purdue University

The generation of Kerr frequency combs in a coherently driven nonlinear microresonator is now extensively investigated more generally by the research community as a potentially portable technology for a variety of applications. Here, we report experiments in which dark pulse combs are formed in normal-dispersion microresonators with mode-interaction-assisted excitation, and mode-locking transitions are observed in the normal-dispersion regime. The mode-interaction-aided excitation of dark pulses appears to occur through a deterministic pathway, in sharp contrast to the situation for bright pulses in the anomalous dispersion region. The ability to mode-lock in the normal-dispersion regime increases the freedom in the microresonator design and may make it possible to extend Kerr comb generation into the visible, where material dispersion is likely to dominate. 

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