Development of a Novel Surface Processing System Using Femtosecond Pulse Train

Yusuke Fukuta; Terutake Hayashi; Masaki Michihata; Yasuhiro Takaya

doi:10.4028/www.scientific.net/KEM.523-524.220

Paper Titles

Experimental Verification of Effect of Grinding Fluid Excited by Ultrasonic Vibration
p.197

Influence of Different Steel Alloys on the Machining Results in Ultrasonic Assisted Diamond Turning
p.203

Investigation of Cutting Phenomena in High Speed Ultrasonic Turning
p.209

Investigation of Ultrasonic-Assisted Drilling of Al/SiC Metal Matrix Composite with Taguchi Method
p.215

Development of a Novel Surface Processing System Using Femtosecond Pulse Train
p.220

Development of the Hole Generation Technology for Aircraft CFRP Parts
p.226

High Efficiency and Eco-Friendly Heat Treatment of Small Parts with a Low-Power Diode Laser Beam
p.232

Novel System Technology for Trepanning a Laser Beam at Arbitrary Developments of Angle of Incidence and Lateral Focus Position
p.238

Thermal Conductivity of Metal Powder and Consolidated Material Fabricated via Selective Laser Melting
p.244

HomeKey Engineering MaterialsKey Engineering Materials Vols. 523-524Development of a Novel Surface Processing System...

Development of a Novel Surface Processing System Using Femtosecond Pulse Train

Abstract:

When a laser pulse interacts with metal or semiconductor target, the coherent phonon, which is the coherent motions of lattice and molecule vibrations in solids, is excited by the interaction of electrons and high latitude electric field. It has unique properties of decaying in approximately several picoseconds and substance specific frequency. Owing to that, femtosecond laser processing is the local processing with little heat diffusion and little thermal damage to the target, due to the ultrafast time scales. We propose a novel femtosecond pulse ablation process with oscillation of the coherent phonon by femtosecond pulse train. The pulse train is shaped using Spatial Light Modulator (SLM), which shift the phase of the passing light. And coherent phonon oscillations are enhanced and decayed due to the controlling the shape of pulse train. It is able to activate the lattice motion for processing efficiently, and hence the target is expected to be ablated with high accuracy and less thermal damage.