Published February 21, 2025 | Version v1

Direct laser interference patterning using fiber Laser: Unleashing new possibilities for industrial applications

  • 1. SurFunction GmbH
  • 2. ROR icon TU Dresden
  • 3. ROR icon Fraunhofer Institute for Material and Beam Technology

Description

This study presents a pioneering advancement in the application of Direct Laser Interference Patterning (DLIP) by integrating it with a high-power, multimode nanosecond fiber laser based on an innovative technology called Extended Laser Interference Patterning System (ELIPSYS®, SurFunction GmbH). This configuration demonstrated the ability to create well-defined interference patterns with a periodicity of 24 µm over a deep focus range of approximately 0.6 mm, making it suitable for large-area surface microprocessing. The influence of laser parameters, particularly pulse energy () and pulse-to-pulse overlap (, on the depth and quality of the laser-produced structures is investigated. By taking into consideration both structure depth and its variation across the patterned area, an optimal process window for superior structure quality is identified. Considering a relative deviation lower than 15 % in the structure depth, periodic structures with a 24.0 µm spatial period and depths from ∼1.0 µm to 18.7 µm could be fabricated with pulse overlaps from ∼60 % to 95 % and pulse energies from 20 mJ to 50 mJ.

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Additional details

Funding

European Commission
CLASCO - Climate Neutral and Digitalized Laser Based Surface Functionalization of Parts with Complex Geometry 101091373