journal article
Open Access
Mar 26, 2026
CO2 Laser Micromachining of PTFE-Based PCBs: Predictive Modeling of Kerf Depth Through Design of Experiments
Abstract
The escalating demand for miniaturization in electronics necessitates advanced laser micromachining for precise micro-via fabrication in PTFE-based PCBs. This study addresses challenges in controlling CO2 laser kerf depth in PTFE, a material known for properties that complicate material removal. Employing a two-level full factorial Design of Experiments, the effects of number of loops, aperture, and pulse duration were systematically investigated. This analysis revealed that while pulse duration statistically impacted ablation depth, the number of loops was operationally most critical due to its direct proportionality with kerf depth in PTFE, leveraging its low thermal conductivity. Aperture, defining the laser spot size, was often constrained by PCB geometric specifications. The predictive models developed demonstrated robust generalizability across different PTFE-based laminates. Validation of the production of PCBs achieved a 100% success rate in meeting geometric tolerances and surface integrity. This DoE-based framework establishes a process window, significantly reducing parameter identification time and scrap, thereby enhancing manufacturing yield.
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Details
- Published
- Mar 26, 2026
- Vol/Issue
- 17(4)
- Pages
- 404
- License
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Authors
Cite This Article
Giorgio Pellei, Paolo Di Stefano, Luca Mascalchi, et al. (2026). CO2 Laser Micromachining of PTFE-Based PCBs: Predictive Modeling of Kerf Depth Through Design of Experiments. Micromachines, 17(4), 404. https://doi.org/10.3390/mi17040404
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