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06.01.2025 11:26

Ferdinand-Braun-Institut presents laser novelties at Photonics West 2025

Petra Immerz Pressestelle
Ferdinand-Braun-Institut gGmbH Leibniz-Institut für Höchstfrequenztechnik

The Berlin-based institute develops tailored diode lasers for use in industry, medical and quantum technologies – from chips to prototypes.At Photonics West 2025 in San Francisco (USA), the Ferdinand-Braun-Institut (FBH) will be presenting novel and advanced diode lasers – at the trade fair (German Pavilion) as well as the accompanying conferences.

At Photonics West 2025 in San Francisco (USA), the Ferdinand-Braun-Institut (FBH) will be presenting novel and advanced diode lasers. FBH will be participating in both the trade fair (January 28-30, 2025) and the accompanying conferences (January 25-30, 2025) with 18 scientific talks. At stand 4205-18 in the German Pavilion, the institute will be showcasing its full range of capabilities – from design and chip development to modules and prototypes. In addition to advanced semiconductor-based light sources, it will introduce novel quantum light modules as well as its high-performance direct-diode laser system “Samba”.

In an invited talk, an FBH team will present their Raman spectroscopic investigations using its inhouse developed 785 nanometer (nm) dual-wavelength diode lasers. The study focused on dyed and natural textiles, as well as black plastics, analyzed with Shifted Excitation Raman Difference Spectroscopy (SERDS). The results highlight the method's potential for the recycling industry, demonstrating its ability to clearly identify the materials examined. This advancement represents an important step towards improving material sorting and recycling efficiency.

Exhibits include:

High-performance monolithic grating-stabilized diode lasers for industrial production and laser fusion

Through advancements in chip design and packaging technology, FBH has achieved significant progress with its diode lasers. The output power and efficiency of industrially applicable, monolithic grating-stabilized diode lasers have been increased whilst new wavelengths have been made available for the first time. Among other things, the institute reached record values for diode lasers operating at 880 nm in cooperation with the industrial partner Trumpf. These achieved maximum continuous-wave output powers of 26 watts with a spectral width of 1 nm from grating-stabilized (DBR) 885 nm single emitters featuring a stripe width of 200 micrometers. They are soon be used as next-generation laser bars in industrial production lasers for pumping Nd:YAG solid-state lasers. These diode lasers also lay the foundation for future pulsed applications that require extremely high output powers. These include pump lasers targeting energy generation through laser fusion, a field in which grating-stabilized lasers in the 870 - 885 nm range play an important role.

At the heart of the “Samba” laser system, which will also be presented, are high-power diode laser submodules that emit at 780 nm. Two of these submodules, which consist of stacked single emitters each with an aperture of 1.2 millimeters (mm) – so-called stacks – are integrated into the compact “Samba” laser head. This allows the power to be scaled up and hence deliver one kilowatt of continuous-wave output power to the workpiece in a precise laser beam with a diameter of just 1 mm. Industrial partners integrate this direct-diode laser system on a robot arm to use it for efficient additive manufacturing of aluminum in industrial laser wire processing. The FBH diode lasers developed for this purpose are up to four times more efficient than conventional lasers operating at around 1030 nm, due to the higher absorption at 780 nm. The technology will be demonstrated in the first step using a laser wire coating process in which the side walls of high-speed trains are produced with significantly reduced weight. Due to its compact size, the innovative system can also be used to fabricate complex components. It does not require an optical fiber and is therefore less prone to downtime due to fiber breakage. Moreover, the wavelength can be further adapted to suit the desired material absorption.

Quantum light modules – analytics, sensor technology, and imaging with entangled photons

The FBH develops quantum light modules based on entangled photon pairs that can be used in a wide range of applications. One of the institute's miniaturized sensor modules will be presented at the trade fair. This module is the core element of a mobile system designed to analyze microplastics on site in aquatic environments for the first time. Measurements are carried out exclusively in the near-infrared range (NIR); neither detectors nor mid-infrared (MIR) radiation sources are required. This reduces costs, as detectors and cameras are less expensive in the NIR than in the MIR spectral range. Even the smallest concentrations and sizes of specific plastics can be detected with the system.

For its quantum light modules, the FBH integrates advanced laser diodes with further components into the most compact of spaces. Inside the modules, an intense laser beam hits a non-linear optical crystal. This causes the photons of the laser beam to split into entangled photon pairs – with both photons possessing different wavelengths. The photons with the MIR wavelength are guided to a sample and back into the sensor module. While the photons with the NIR wavelength remain inside the module. After the respective photon pairs have exchanged information, only NIR photons are analyzed. This method is ideally suited for applications in medicine, metrology, microscopy, and environmental analysis.

Master oscillator power amplifier with excellent optical properties

Researchers at FBH have developed a miniaturized master oscillator power amplifier (MOPA) that delivers more than eight watts of optical output power in continuous-wave operation yielding a narrow spectral width (< 100 MHz) and a high beam quality (M² < 2). It can be used in a wide range of applications, from medicine and metrology to quantum physics. Thanks to its small dimensions of just 25 x 25 mm², it enables compact and mobile instruments. To protect the MOPA against optical feedback, it is equipped with a miniaturized optical isolator. The MO is spectrally stabilized by an internal distributed Bragg reflector (DBR), while a tapered amplifier was chosen for the PA. The compact CCP3 mount can be easily integrated into measurement setups and systems. As an option, the MOPA can also be built into a closed butterfly housing. Wavelengths are flexibly adjustable in the range between 620 - 180 nm.

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Weitere Informationen:

https://www.fbh-berlin.de/en/events/spie-photonics-west-2025 - overview comprising all FBH talks at Photonics West

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Miniaturized master oscillator power amplifier (MOPA) with interposed optical isolator mounted on CC ...
Petra Immerz
FBH/P. Immerz

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High-power diode laser submodule - two of such stack modules are integrated into the Samba laser hea ...
Petra Immerz
FBH/P. Immerz

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Merkmale dieser Pressemitteilung:
Journalisten, Studierende, Wirtschaftsvertreter, Wissenschaftler
Energie, Medizin, Physik / Astronomie, Werkstoffwissenschaften
überregional
Forschungs- / Wissenstransfer, Wissenschaftliche Tagungen
Englisch

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