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A Harvard-led team created the first self-contained, chip-based laser that pulses in the mid-infrared – ideal for advanced gas sensing and imaging. This innovation could power next-gen tools for climate science and healthcare. Credit: SciTechDaily.com
Physicists at Harvard have developed a powerful new laser-on-a-chip that emits bright pulses in the mid-infrared spectrum – an elusive and highly useful light range for detecting gases and enabling new spectroscopic tools.
The device, which packs capabilities of much larger systems into a tiny chip, doesn’t need any external components. It merges breakthrough photonic design with quantum cascade laser tech and could soon revolutionize environmental monitoring and medical diagnostics by detecting thousands of light frequencies in one go.
Breakthrough in Compact Mid-Infrared Laser Technology
Physicists at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) have developed a compact laser that emits bright, ultra-short pulses of light in the mid-infrared spectrum – a wavelength range that is both scientifically valuable and technically challenging to achieve. The device delivers the performance of much larger photonic systems but fits entirely onto a single chip.
Published today (April 16) in Nature, the study marks the first demonstration of an on-chip, picosecond mid-infrared laser pulse generator that operates without any external components. The laser can generate an optical frequency comb – a spectrum made up of evenly spaced frequencies – widely used for high-precision measurements. This compact platform could help enable new generations of broad-spectrum gas sensors for environmental monitoring, as well as advanced spectroscopy tools for medical imaging.
International Team and Strong Support Network
The research was led by senior author Federico Capasso, the Robert L. Wallace Professor of Applied Physics at SEAS and Vinton Hayes Senior Research Fellow in Electrical Engineering. Funded by the National Science Foundation and the Department of Defense, the project was a collaboration with the Schwarz group at the Vienna University of Technology (TU Wien), a team of Italian researchers led by Luigi A. Lugiato, and Leonardo DRS Daylight Solutions under the direction of Timothy Day.
“This is an exciting new technology that integrates on-chip nonlinear photonics to generate ultrashort pulses of light in the mid-infrared; no such thing existed until now,” Capasso said. “What’s more, such devices can be readily produced at industrial laser foundries using standard semiconductor fabrication.”
Artist’s impression of the mid-infrared laser chips with light paths connecting the components. Credit: Runke Luo
Mid-Infrared’s Power in Gas Detection
The mid-infrared is an invisible section of the electromagnetic spectrum that is leveraged today in environmental applications. Because many gas molecules like carbon dioxide and methane absorb mid-infrared light efficiently, this wavelength range has been an important tool in monitoring environmental gases, notably with quantum cascade laser technology that was pioneered by Capasso in the 1990s.
The new paper demonstrates a path to generating a broadband light source that could detect, for example, many different absorption fingerprints of gases in a single device.
“It’s a key step to creating what we call a supercontinuum source, which can generate thousands of different frequencies of light, all in one chip,” said Dmitry Kazakov, co-first author and research associate in Capasso’s group. “I think that’s a real possibility for the future of this platform.”
Overcoming Pulse Challenges in QCLs
Fundamental to the new feat of nanophotonic engineering is the quantum cascade laser, which generates coherent beams of mid-infrared light by layering together different nanostructured semiconductor materials. Unlike other semiconductor lasers that have relied for decades on well-established techniques called mode-locking to generate their pulses, quantum cascade lasers remain notoriously difficult to pulse due to their inherently ultra-fast dynamics.
Existing mid-infrared pulse generators based on quantum cascade lasers typically require complex setups to achieve pulsed emission as well as many discrete hardware components. They are also generally limited to a certain output power and spectral bandwidth.
Optical microscope image of the quantum cascade photonic integrated chip. Shown chip contains two identical devices each comprising four components: a Fabry-Perot drive laser, a waveguide coupler, a resistive heater, and a racetrack resonator. Credit: Capasso Lab / Harvard SEAS
Solving Pulsing with Solitons and Microresonators
The new pulse generator seamlessly combines, into a single device, several concepts in nonlinear integrated photonics and integrated lasers to make specific types of picosecond light pulses called solitons. In designing their chip architecture, the researchers took inspiration from a seemingly unrelated type of light-modulating device called a Kerr microresonator. Their creative thinking allowed them to skirt traditional techniques, like mode-locking, for pulse generation.
“Our measurements were non-traditional when it came to quantum cascade laser research,” said co-first author Theodore Letsou, a graduate student at MIT and research fellow in Capasso’s group. “We merged two types of fields and took what the Kerr resonator community does and applied it to our systems. That was an exciting process.”
“For me, the most significant impact of our new work – beyond the impressive physics – is the confidence it has given us in fabricating and operating multicomponent architectures, which is a capability that had remained a major challenge in mid-infrared integrated photonics until now,” said paper co-author Benedikt Schwarz, professor at TU Wien. “We’re already developing new architectures to enable functionalities previously thought impossible.”
Theory from the 1980s Meets Modern Lasers
The researchers drew on a foundational theory published in the 1980s that established a framework for passive Kerr resonators. One of the new paper’s co-authors is Luigi Lugiato, who worked on repurposing his original equation to describe the dynamics of the mid-IR laser system.
“This is an exciting culmination of a journey that began with the Lugiato-Lefever equation,” said Lugiato, professor emeritus at University of Insubria, Italy. “What started as a model for passive systems has evolved into a unified framework for soliton frequency combs in all kinds of cavities. That path led us to predict solitons in optically driven quantum cascade lasers above threshold – now confirmed by this experiment.”
Ready for Scale: Industrial Fabrication-Friendly Design
The new mid-infrared laser can reliably maintain pulse generation for hours at a time. Crucially, it can also be mass-produced using existing industrial fabrication processes, which could greatly increase the speed of its widespread adoption. The device is made of a ring resonator that can be externally driven; an on-chip laser that drives the ring resonator; and a second active ring resonator that acts as a filter. The chips were made at TU Wien.
“This technology promises to be a real game-changer in the field of mid-infrared spectroscopy,” said paper co-author Timothy Day, Senior Vice President and General Manager of Leonardo DRS’ Daylight Solutions business unit. “The ability to leverage existing fabrication processes to produce these devices in commercial volumes could really enable what’s next in several markets, including environmental monitoring, industrial process control, life sciences research, and medical diagnostics.”
Reference: “Driven bright solitons on a mid-infrared laser chip” 16 April 2025, Nature.
DOI: 10.1038/s41586-025-08853-y
The research is based on work supported by the National Science Foundation under Grant No. ECCS2221715. Other sources of funding included the Department of Defense through the National Defense Science and Engineering Graduate Fellowship Program, and the European Research Council.
Harvard’s Office of Technology Development has protected the innovations associated with this research and is exploring commercial opportunities.
Other co-authors of the paper are Marco Piccardo, Lorenzo L. Columbo, Massimo Brambilla, Franco Prati, Sandro Dal Cin, Maximilian Beiser, Nikola Opačak, Pawan Ratra, Michael Pushkarsky, and David Caffey.
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