The demand for micro/nano-fabrication is rapidly increasing with the continuous miniaturization of industrial devices. Ultrafast laser technology has emerged as a promising solution, offering high peak power, minimal heat-affected zones, and nonlinear processing capabilities. However, the complex interplay between laser parameters and resulting micro/nanostructures necessitates precise modeling for intuitive morphology control and effective process optimization. Therefore, this study proposes a novel multiphysics-coupled 3D visualization model that integrates ablation dynamics, phase transition behavior, and dynamic mesh technology. The model establishes a cross-scale mapping between surface node motion and staged ablation rates by coupling ablation and phase transition dynamics with dynamic meshing to reveal the mechanisms of micro-hole formation and quantitatively link feature size to single-pulse laser parameters. Experimental validation based on femtosecond laser pulses with varying energies showed high consistency between simulations and measurements in ultrafast laser-induced micro-hole morphology control, with prediction errors of less than 5.3% and 7.8% for micro-hole diameter and depth, respectively, achieved without prior optimization. This study provides meaningful insights into ultrafast laser-induced microstructure control and serves as a practical reference for semiconductor chip design.
Ran et al. (Thu,) studied this question.
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