Shaped CO2 Pulses Cleanly Ablate Silica Glass

Although excimer and ultrafast laser technology can machine silica glass, the high average power and material removal rate of CO₂ lasers is more practical for machining large surface areas, provided that feature sizes are greater than 10 µm. Conventional CO₂ configurations, however, create surface roughness by molten material ejection or displacement of irradiated glass.

Researchers at Heriot-Watt University in Edinburgh, UK, have reported an approach to laser-machining silica glass by ablation that uses an acousto-optical modulator to shape the output of a CO₂ laser. They demonstrated that rectangular pulses with widths of 30 to 50 µs allowed greater control over the ablation process, with material evaporating smoothly from the surface at temperatures of about 3000 °C. By avoiding melt ejection or melt displacement, the technique produced machined silica with improved surface smoothness.

The researchers describe their system and experimental results in the Sept. 20 issue of Applied Optics.





LATEST NEWS

• Hiphen Acquires Aurea Imaging’s Phenotyping Activities: Week in Brief: 1/17/25
  Jan 17, 2025
• IonQ Awarded $21.1M Quantum Networking Project
  Jan 17, 2025
• Quantum Brilliance Raises $20M
  Jan 16, 2025
• Scalable Error-Correction Signals Forthcoming Efficiency Gains for Quantum Compute
  Jan 16, 2025
• Fraunhofer CAP Appoints Head, Scientific Director: People in the News: 1/15/25
  Jan 15, 2025
• Bioluminescent Tags Track RNA Dynamics in Live Cells in Real Time
  Jan 15, 2025
• Sensing and Inspection Specialist EVK Joins Headwall Group
  Jan 14, 2025
• PHOTON IP Raises $4.9M Seed Round
  Jan 14, 2025