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06/03/2025 08:36

More efficient circuits for AI and quantum computers

Desiree Haak Press & Public Relation
Fraunhofer-Institut für Angewandte Optik und Feinmechanik IOF

    Lithium niobate has long been a standard material for modulating optical signals, both in telecommunications and in laser amplifiers. Researchers at the Fraunhofer Institute for Applied Optics and Precision Engineering IOF have further developed thin-film lithium niobate (LNOI) to build integrated optical circuits. This is a breakthrough for photonic integrated circuits that enable energy-efficient, fast and scalable photonic systems. The technology will be presented at the World of Quantum trade fair in Munich from June 24 to 27.

    Photonic integrated circuits (PICs) differ from electrical ICs: they have waveguides instead of electrical conductors and the light signals are processed in small interferometers instead of transistors or gates. Both waveguides and interferometers can be manufactured excellently in lithium niobate. The researchers at Fraunhofer IOF can realize these structures in thin-film lithium niobate grown on an insulating material (LNOI). The process uses technology from semiconductor manufacturing and is therefore immediately scalable.

    Quantum computers with photons

    "With LNOI technology, we can produce photonic components with a very high bandwidth, low power-loss and compact design," comments Dr. Falk Eilenberger, Head of the Department of Micro- and Nanostructured Optics at Fraunhofer IOF. "These are properties that are crucial for future applications in communication and data processing," adds Dr. Frank Setzpfandt. Setzpfandt is a researcher at the Friedrich Schiller University Jena. Together with other partners, the teams around him and Eilenberger are active in the PhoQuant research project, a project funded by the German Federal Ministry of Research, Technology and Aeronautics (BMFTR, formerly BMBF), in which context the technology was developed and is also to be used.

    PhoQuant aims to develop a quantum computer that uses optical technologies. Such a photonic quantum computer does not require the complex cooling as needed for other quantum computers. It uses quantum light sources that generate special states of light and processes them in integrated LNOI structures. The resulting optical signals can be measured or interact with other qubits in the quantum internet.

    Optical circuits for data centers and AI

    However, LNOI technology also works for normal laser signals. Laser technology has revolutionized data transmission in recent decades and has made a significant contribution to making transmission rates in the Gbit and Tbit/s range possible today.

    Some properties of light are now also helping to make data processing at processor level considerably faster. It is important to note that light signals enable a much higher bandwidth. As light signals of different wavelengths can be easily superimposed, optical processors can even process several signals simultaneously in the same "line", i.e., the same waveguide.

    The LNOI technology developed in the PhoQuant project at Fraunhofer IOF has the advantage that it allows processing speeds in the 100 GHz range. The control voltage for the modulators is in the range of a few volts - a special feature of the Jena technology. "This offers significant advantages in the application of optical integrated circuits," explains Dr. Eilenberger. In addition to the modulators, the team from Jena is developing a whole range of integrated optical components based on LNOI.

    The optical circuits are suitable for various special tasks, including typical artificial intelligence tasks. "In the future, optical computers will perform such tasks faster and much more energy-efficiently than conventional circuits," says Dr. Eilenberger, describing the future of LNOI technology.

    Presentation at the World of Quantum 2025

    Interested visitors to World of Quantum can experience Fraunhofer IOF's LNOI technology, including various integrated optical components, at the PhoQuant booth A1.439. Another exhibit will be on display at Laser World of Photonics at the central Fraunhofer IOF information booth A2.415.

    About Fraunhofer IOF

    The Fraunhofer Institute for Applied Optics and Precision Engineering IOF in Jena conducts application-oriented research in the field of photonics and develops innovative optical systems for controlling light - from its generation and manipulation to its application. The institute's range of services covers the entire photonic process chain from opto-mechanical and opto-electronic system design to the production of customer-specific solutions and prototypes. At Fraunhofer IOF, about 500 employees work on the annual research volume of 40 million euros.

    For more information about Fraunhofer IOF, please visit: http://www.iof.fraunhofer.de


    Contact for scientific information:

    Dr. Falk Eilenberger
    Fraunhofer IOF
    Head of Department Micro- and Nanostructured Optics

    Phone: +49 (0) 3641 807 - 274
    Mail: falk.eilenberger@iof.fraunhofer.de


    More information:

    https://www.iof.fraunhofer.de/en/pressrelease/2025/More-efficient-circuits.html


    Images

    Integrated optical circuit with fiber optic connections (top and bottom). The modulator  signals are fed in via the gold electrodes on the sides.
    Integrated optical circuit with fiber optic connections (top and bottom). The modulator signals are ...

    © Fraunhofer IOF

    The team at Fraunhofer IOF has developed both the optical and electrical connection  technology for the LNOI circuits.
    The team at Fraunhofer IOF has developed both the optical and electrical connection technology for ...

    © Fraunhofer IOF


    Criteria of this press release:
    Business and commerce, Journalists, Scientists and scholars
    Electrical engineering, Information technology, Physics / astronomy
    transregional, national
    Research projects, Research results
    English


     

    Integrated optical circuit with fiber optic connections (top and bottom). The modulator signals are fed in via the gold electrodes on the sides.


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    The team at Fraunhofer IOF has developed both the optical and electrical connection technology for the LNOI circuits.


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