Time-resolved quantification of plasma accumulation induced by multi-pulse laser ablation using self-mixing interferometry

TL;DR

This paper introduces a self-mixing interferometry method to rapidly measure plasma density during multi-pulse laser ablation, providing insights into plume dynamics for improved manufacturing control.

Contribution

A novel analytical model linking SMI signals to plasma electron density, enabling time-resolved plasma quantification during laser ablation.

Findings

SMI accurately estimates plasma electron density over time.

Plume expansion follows a power-law scaling.

Method applicable for real-time monitoring in manufacturing.

Abstract

In this work a method based on self-mixing interferometry (SMI) is presented for probing the concentration of plasma plumes induced by multi-pulse laser ablation. An analytical model is developed to interpret the single-arm interferometric signal in terms of plasma electron number density. Its time dependence follows a power-law scaling which is determined by concurrent effects of plume accumulation and propagation. The model has been applied for the experimental study of plume formation at variable laser pulse frequencies on different materials. The plume expansion dynamics has been observed with high-speed imaging, and the SMI measurements allowed for a time-resolved estimation of the electron number density. The intrinsic advantages of the SMI technique in terms of robustness and low intrusiveness would allow for its usage as a fast diagnostic tool for the dynamical scaling of laser-induced plumes. Moreover it can be easily applied in laser-based manufacturing technologies where plasma concentration monitoring and control is important.