Theoretical simulation and experimental verification of dynamic caustic manipulation using a deformable mirror for laser material processing

TL;DR

This paper combines theoretical simulations and experimental tests to demonstrate how deformable mirrors can manipulate laser caustics for precise material processing, showing high linearity and application potential.

Contribution

It introduces a method to control laser caustics using deformable mirrors, validated through simulations and experiments, for improved laser material processing.

Findings

Deformable mirror reduces initial beam astigmatism.

Achieved high linearity in focus shift ($R^2 >98$%).

Demonstrated slit drilling in metal foils.

Abstract

The influence of a deformable mirror on spatial light modulation in ultrafast lasers processing is demonstrated. The deformable mirror was integrated into an optical setup which contains an additional lens for generating a nearly linear focus shift in the focal plane behind the f-theta lens. The deformation of the mirror surface can be described by the Zernike terms Defocus, Astigmatism, and a combination of both, resulting in a cylindric lens behavior. The influence of the mirror surface deformation in this optical setup on the intensity distribution in the focal plane was simulated. From the simulation results, the caustic in the focal plane was calculated. The simulation results were compared to experiments using a picosecond laser with a maximum pulse energy of about 60 $\mu$J. We demonstrate that the initial astigmatism of the raw beam can be reduced using the deformable mirror. High linearity in the focus shift ($R^2 >98$%) and the generation of elliptical/ line intensity distributions are shown. Line intensity distribution was used to demonstrate slit drilling application in thin metal foils.