Plume dynamics and nanoparticle formation in ultra-short laser ablation of metals

TL;DR

This paper investigates nanoparticle formation during femtosecond laser ablation of metals, combining simulations and analysis to understand plume dynamics and size distribution evolution under various conditions.

Contribution

It provides a detailed numerical analysis of plume expansion and nanoparticle formation, highlighting the transition from initial distribution to bell-shaped and the role of catastrophic nucleation.

Findings

Nanoparticle size distribution evolves from decreasing to bell-shaped within 50 microseconds.

Supersaturation enables prolonged diffusion-driven nanoparticle growth.

Results explain experimental observations and predict plume evolution and size distribution changes.

Abstract

Nanoparticle formation by femtosecond laser ablation is investigated for different experimental conditions. Dynamics of the laser plume expansion is visualized based on numerical simulations and the possibility of primary nanoparticle formation is analyzed. Calculations are performed for metals under different background conditions. The effects of the background environment are considered, including initial expansion stage of the ejected atoms and clusters, nucleation, collisions, and longer scale nanoparticle evolution. Nanoparticle size distribution is shown to evolve from a decreasing function to the commonly observed bell-shaped distribution as early as at 50 microseconds after the beginning of the laser pulse. However, at the end of the initial plume expansion stage, the supersaturation parameter can be sufficiently high for a much longer diffusion-driven nanoparticle growth to enter into play. In this case, the major nanoparticle formation process is based on the so-called catastrophic nucleation accompanied by collisional growth, which determines the final size distribution. The obtained calculation results explain numerous experimental findings and help to predict both nanoparticle plume evolution and changes in its size distribution.