Fiber optic components enable high-performance 2-µm fiber lasers

Fiber optic components enable high-performance 2-µm fiber lasers Lisa Lock Scientific Editor Robert Egan Associate Editor Laser systems operating in the 2-micrometer wavelength range open diverse opportunities in medical technology, agriculture, and plastics processing. In the Eurostars project DECOMP, Laser Zentrum Hannover e.V. (LZH) has developed novel fiber optic components that overcome previous technical barriers. Thulium-doped fiber lasers operate at a wavelength of approximately 2 micrometers, making them particularly well-suited for applications where conventional lasers reach their limits. However, commercially available laser sources that simultaneously offer high beam quality, sufficient laser power, and the necessary reliability in quasi-continuous-wave operation at power levels around 1 kilowatt have been lacking. In the project, LZH scientists developed novel fiber optic components based on triple-clad fibers that enable a reliable and low-maintenance laser architecture. For the implementation of the final laser system, LZH collaborated with Futonics Laser GmbH as well as South Korean partners COSET, inc. and the Korean Photonics Technology Institute. The LZH scientists utilized an innovative CO₂ laser-based processing technology developed and patented by LZH. With this technology, they selectively removed small areas of the outermost glass cladding of the triple-clad fibers, creating lateral access to the pump cladding. This technique enables pump diode fibers to be spliced laterally to the pump light cladding, i.e., the inner glass cladding, thereby providing the required pump energy for the laser process. Additionally, the researchers developed cladding mode strippers that efficiently remove unabsorbed pump light from the fiber system through CO₂ laser structuring of the triple-clad fiber. High coupling efficiency at 475 watts input power The developed signal-pump couplers achieved an average coupling efficiency of 90.1±2.5% at input powers up to 475 watts, with the available pump power being the limiting factor. This achieves an efficiency that corresponds to the state of the art for couplers with conventional fibers. For triple-clad fibers, as used here, this represents a significant new development. The low optical losses indicate that the component can also be operated at significantly higher powers, making it possible to reach the targeted 1 kW power class. For the cladding mode strippers, the scientists achieved an outcoupling efficiency of more than 20 dB with a derived optical power of 250 watts. These components make the triple-clad fiber design usable for various laser and amplifier configurations and enable higher fiber integration as well as further power scaling in systems with demanding beam quality requirements. Provided by Laser Zentrum Hannover e.V.