A team of researchers led by Qiang Lin, a professor of electrical and computer engineering at Rochester, has developed the first multi-color integrated Pockels laser that emits high-coherence light at telecommunication wavelengths, allows laser-frequency tuning at record speeds, and is the first narrow linewidth laser with fast configurability at the visible band.

A laser that could ‘reshape the landscape of integrated photonics’

Rochester researchers see applications in LiDAR, atomic physics, AR/VR.

A team of researchers led by Qiang Lin, a professor of electrical and computer engineering at Rochester, has developed the first multi-color integrated Pockels laser that emits high-coherence light at telecommunication wavelengths, allows laser-frequency tuning at record speeds, and is the first narrow linewidth laser with fast configurability at the visible band.

A team of researchers led by Qiang Lin, a professor of electrical and computer engineering at Rochester, has developed the first multi-color integrated Pockels laser that emits high-coherence light at telecommunication wavelengths, allows laser-frequency tuning at record speeds, and is the first narrow linewidth laser with fast configurability at the visible band. (University of Rochester photo / J. Adam Fenster)

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October 21, 2022

How do you integrate the advantages of a benchtop laser that fills a room onto a semiconductor chip the size of a fingernail?

A research team co-led by Qiang Lin, a professor of electrical and computer engineering at the University of Rochester, has set new milestones in addressing this challenge, with the first multi-color integrated Pockels laser that:

  • Emits high-coherence light at telecommunication wavelengths
  • Allows laser-frequency tuning at record speeds
  • Is the first narrow linewidth laser with fast configurability at the visible band

The project, described in Nature Communications, was co-led by John Bowers, distinguished professor at University of California/Santa Barbara, and Kerry Vahala, professor at the California Institute of Technology. Lin Zhu, professor at Clemson University, also collaborated on the project.

The technology “has the potential to reshape the landscape of integrated photonics,” write co-lead authors Mingxiao Li, a former PhD student in Lin’s Laboratory for Nanophotonics at Rochester’s Hajim School of Engineering & Applied Sciences, and Lin Chang, a former postdoctoral student at University of California/Santa Barbara.

It will pave the way for new applications of integrated semiconductor lasers in LiDAR (Light Detection and Ranging) remote sensing that is used, for example, in self-driving cars. The technology could also lead to advances in microwave photonics, atomic physics, and AR/VR.

A ‘fully on-chip laser solution’

Integrated semiconductor lasers have been at the core of integrated photonics, enabling many advances over the last few decades in information technologies and basic science.

A schematic of a new type of integrated semiconductor laser, developed by a team of researchers led by Qiang Lin
A schematic of a new type of integrated semiconductor laser, developed by a team of researchers led by Qiang Lin, which has the “potential to reshape the landscape of integrated photonics.” (Drawing by Mingxiao Li)

“However, despite these impressive achievements, key functions are missing in current integrated lasers,” Li says. “Two major challenges, the lack of fast reconfigurability and the narrow spectral window, have become major bottlenecks that stall the progression of many evolving applications,” Chang adds.

The researchers say they’ve overcome these challenges by creating a new type of integrated semiconductor laser, based on the Pockels effect. The laser is integrated with a lithium-niobate- on-insulator platform.

The new technology includes these beneficial features:

  • Fast frequency chirping, which will be invaluable in LiDAR sensor systems, which measure distance by recording the time between emission of a short pulse and reception of reflected light.
  • Frequency conversion capabilities that overcome spectral bandwidth limitations of traditional integrated semiconductor lasers. This will “significantly relieve” the difficulties in developing new wavelength lasers.
  • Narrow wavelength and fast reconfigurability, providing a “fully on-chip laser solution” to probe and manipulate atoms and ions in atomic physics, and benefit AR/VR and other applications at short wavelengths.

Other coauthors from Lin’s group include postdoctoral associate Yang He and graduate students Jingwei Lin, Shixin Xue, Jeremy Staffa, Raymond Lopez-Rios, and Usman Javid.

The research was supported by funding from the Defense Advanced Research Projects Agency (DARPA), the Defense Threat Reduction Agency-Joint Science and Technology Office for Chemical and Biological Defense, and the National Science Foundation.

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