Português

Renowned companies such as TRUMPF and Jenoptik participate in high-power laser projects in Germany

1213
2024-11-09 11:12:32
Ver tradução

High power laser diodes will be key components of future fusion power plants.
Recently, the German Federal Ministry of Education and Research (BMBF) launched a new project called "DioHELIOS". The project will last for 3 years and is part of BMBF's "Fusion 2040" funding program, which aims to build the first nuclear fusion power plant in Germany by 2040.

The project will last for three years and receive funding support of 17.3 million euros. Its goal is to promote the application of high-power laser diodes in fusion power plants, which the German government expects to be built as early as the 2040s.

The DioHELIOS project brings together top institutions and laser optoelectronic manufacturers such as ams OSRAM, Ferdinand Brown Institute (FBH), Leibniz Institute for High Frequency Technology (HZDR), Fraunhofer Institute for Laser Technology (ILT), Jenoptik, Laserline, and TRUMPF to enhance the power and efficiency of high-power laser diodes and develop automated mass production processes to meet the enormous energy demand generated by laser inertial confinement fusion.


The above figure shows the most advanced diode stack, consisting of 25 semiconductor bars, with a focusing lens in the front and active cooling at the back. (Image source: TRUMPF)

The core of the project is to develop a beam shaping diode laser module for high-energy laser pumping plate stack amplifiers, which is considered a key component of future nuclear fusion power plants and is supported by the Fraunhofer Institute for Laser Technology (ILT) in Germany.

The project goal is to increase pulse efficiency by 50 times while improving overall efficiency and ensuring uniformity and stability of spectral characteristics. In addition, the project also pursues mass production at a cost of less than 1 cent per watt of power, and hopes that the hardware can operate stably for 30 years at a repetition rate of about 15 hertz.

During the project execution, Laserline and TRUMPF will build different pump modules for high-power laser pumping in the initial demonstrator. The alliance is committed to pushing diode laser based pump modules to the megawatt range.

Jenoptik, Osram, and Ferdinand Brown Institute (FBH), as leading manufacturers and developers of laser diodes, will contribute their expertise to drive innovation in semiconductor laser technology.

The Fraunhofer Institute for Laser Technology (ILT) in Germany uses its SEMSIS software to design and optimize diode laser rods, significantly increasing the output power of chips and ensuring their industrial production at the required cost level and resource efficiency.

The project team is seeking new design methods for diode lasers required for nuclear fusion power plants to stabilize the spectral distribution of laser beams and increase light production through a "multi junction" mode. They plan to significantly improve the efficiency of electron to photon conversion by stacking multiple active regions.

The optimized diode laser chip will be sent to TRUMPF, Laserline, and Jenoptik for building a diode laser stack with high packaging density and high irradiance. An efficient cooling system is crucial for ensuring long lifespan and avoiding temperature induced spectral drift. These stacks will serve as building blocks for pump modules, arranged in a two-dimensional array.

In addition, project partners are also studying the potential of optimizing current drivers to provide current pulses exceeding 1000 amperes and minimize losses as much as possible.

Meanwhile, the Fraunhofer Institute for Laser Technology (ILT) in Germany is developing specially optimized optical devices for automated assembly to collimate and homogenize beam profiles.

Optical components based on welding can achieve long-term stable beam shaping. In the future, AI will accelerate the adjustment of micro optics to achieve the required quantity of commercial power plants and reduce unit costs. (Image source: Fraunhofer ILT)
Ultimately, these partners will evaluate the scalability of the module to achieve higher output and pulse energy, while controlling system costs.

From: Yangtze River Delta Laser Alliance

Recomendações relacionadas
  • New type of metasurface with adjustable beam frequency and direction

    Recently, according to the journal Nature Nanotechnology, a team from the California Institute of Technology reported that they have constructed a metasurface covered with micro adjustable antennas that can reflect incident light beams: one beam of light enters and multiple beams of light exit, each with a different frequency and propagating in a different direction. This is a new method for proce...

    2024-07-30
    Ver tradução
  • Mechanism of Time Power Modulation Increasing Weld Depth in High Power Laser Welding

    Researchers from the Hanover Laser Center and Leibniz University in Germany reported on the mechanism of increased welding depth during time power modulation in high-power laser beam welding. The related paper titled "Mechanisms of Increasing Welding Depth during Temporary Power Modulation in High Power Laser Beam Welding" was published in Advanced Engineering Materials.Understanding the basic mec...

    2024-12-18
    Ver tradução
  • NASA will demonstrate laser communications on the space station to improve space communications capabilities

    Recently, in order to improve the National Aeronautics and Space Administration (NASA) space communications capabilities, NASA plans to send a technology demonstration called "Integrated LCRD Low Earth Orbit User Modem and Amplifier Terminal (ILLUMA-T)" to the space station in 2023.ILLUMA-T and the Laser Communications Relay Demonstration (LCRD), launched in December 2021, will together comp...

    2023-09-04
    Ver tradução
  • The world's most powerful laser attempts to unravel the secrets of the universe

    They are the strongest lasers in history, and their beams are helping scientists explore the structure of the universe.In a research laboratory at the University of Michigan, bright green light fills the vacuum chamber of a technology giant. It is the size of two tennis courts. The walls are shielded with 60 centimeters of concrete to prevent radiation leakage, and workers wear masks and hairnets ...

    2023-11-28
    Ver tradução
  • NKT Photonics utilizes fiber lasers to achieve deep space communication links

    On July 7, the European Space Agency (ESA), established Europe’s first deep-space optical communication link with NASA’s Psyche mission using a high-power fiber laser system supplied by NKT Photonics, a subsidiary of Hamamatsu.NKT’s announcement stated, “This achievement, conducted with NASA/JPL’s Deep Space Optical Communications (DSOC) demonstrator, marks a significant leap forward in high-data-...

    07-21
    Ver tradução