Ελληνικά

Harvard University and University of Vienna invented tunable laser chips

793
2025-07-16 14:42:00
Δείτε τη μετάφραση

Researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) and Vienna University of Technology (TU Wien) have invented a new type of tunable semiconductor laser that shows smooth, reliable, wide-range wavelength tuning in a simple, chip-sized design.
Tunable lasers are integral to many technologies, from high-speed telecommunications to medical diagnostics to safety inspections of gas pipelines. Yet laser technology faces many tradeoffs – for example, lasers that emit across a wide range of wavelengths sacrifice the accuracy of each wavelength. They can also depend on complicated and expensive designs because they commonly require moving parts.

Artist’s illustration of the new tunable ring laser.

The Harvard and Vienna developers new device could “one day replace many types of tunable lasers in a smaller, more cost-effective package.”

The associated research has been published in Optica. It was co-led by Federico Capasso, the Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering at SEAS, and Prof. Benedikt Schwarz at TU Wien.

‘More commercially relevant wavelengths’

The researchers have initially demonstrated a laser that emits light in the mid-infrared wavelength range because that is where quantum cascade lasers, upon which their architecture is based, typically emit. “The versatility of this new platform means that similar lasers can be fabricated at more commercially relevant wavelengths, such as for telecommunications applications, for medical diagnostics, or for any laser that emits in the visible spectrum of light,” said Capasso, who co-invented the quantum cascade laser in 1994.

The new laser consists of multiple tiny ring-shaped lasers, each a slightly different size, and all connected to the same waveguide. Each ring emits light of a different wavelength, and by adjusting electric current input, the laser can smoothly tune between different wavelengths. The clever and compact design ensures the laser emits only one wavelength at a time, remains stable even in harsh environments, and can be easily scaled. The rings function either one at a time or all together to make a stronger beam.

“By adjusting the size of the ring, we can effectively target any line we want, and any lasing frequency we want,” said co-lead author Theodore Letsou, an MIT graduate student and research fellow in Capasso’s lab at Harvard. “All the light from every single laser gets coupled through the same waveguide and is formed into the same beam. This is quite powerful, because we can extend the tuning range of typical semiconductor lasers, and we can target individual wavelengths using a different ring radius.”

“What’s really nice about our laser is the simplicity of fabrication,” added co-lead author Johannes Fuchsberger, a graduate student at TU Wien, where the team fabricated the devices using the cleanroom facilities permanently provided by the school’s Center for Micro and Nanostructures. “We have no mechanically movable parts and an easy fabrication scheme that results in a small footprint.”

The new ring laser could possibly replace current technologies for different types of tunable semiconductor lasers that each have strengths and drawbacks depending on the application. For example, distributed feedback lasers make smooth and accurate beams and are therefore used in telecommunications fiber to send optical signals long distances, but their tuning range is narrow.

External cavity lasers, on the other hand, have broader tuning ranges but more complex designs and moving parts, which makes their laser lines tend to skip around. These are commonly used in gas sensors that test for leaks in pipelines, because they can detect gases like methane and carbon dioxide which absorb light at distinct wavelengths.

Source: optics.org

Σχετικές προτάσεις
  • Progress in the Application of China University of Science and Technology's Femtosecond Laser Processing Technology in the Biomedical Field

    Recently, Associate Professor Li Jiawen's research group at the Micro and Nano Engineering Laboratory of the School of Engineering Science, University of Science and Technology of China proposed a femtosecond laser dynamic holographic processing method suitable for efficient construction of three-dimensional capillary scaffolds, which is used to generate a three-dimensional capillary network. This...

    2024-02-11
    Δείτε τη μετάφραση
  • Uncovering the Secrets of Nature: A New Generation of X-ray Lasers Reveals the Mystery of Atoms

    As a breakthrough leap in scientific exploration, the new generation of powerful X-ray lasers is now targeting the fastest and most basic processes in nature. Their mission: to uncover the complex atomic arrangement that drives these phenomena, providing unprecedented insights into chemical reactions, electronic behavior in materials, and the mysteries of the natural world.Unlocking the precise me...

    2023-09-25
    Δείτε τη μετάφραση
  • ComNav Technologies introduces Mars Pro Laser RTK

    ComNav Technology Ltd. has introduced the Mars Pro Laser RTK, the latest addition to its Universe series GNSS receiver product line, which includes the Venus Laser RTK and Mars Laser RTK. The GNSS receiver is suitable for the land surveying, GIS and construction industries with its innovative features.Mars Pro's laser mode facilitates the use of conventional GNSS receivers in areas where signals a...

    2023-09-13
    Δείτε τη μετάφραση
  • Coherent's revenue for 2024 is $5.301 billion

    International laser giant Coherent's Q4 2024 sales exceeded expectations, reaching a historic high!Recently, Coherent released its highest quarterly sales data in history, mainly due to the demand for optical transceivers in artificial intelligence data center applications. For the three months ending December 31, the company's revenue was $1.43 billion, a year-on-year increase of 27% and a 6% inc...

    02-10
    Δείτε τη μετάφραση
  • SILICON AUSTRIA LABS and EV GROUP Strengthen Cooperation in Optical Technology Research

    EV Group, a leading supplier of wafer bonding and lithography equipment for the MEMS, nanotechnology, and semiconductor markets, and Silicon Austria Labs, a leading electronic systems research center in Austria, announced that SAL has received and installed multiple EVG lithography and photoresist processing systems in its MicroFab at the R&D cleanroom facility in Filach, Austria.These devices...

    2023-11-15
    Δείτε τη μετάφραση