Single-Shot Multi-Stage Damage and Ablation of Silicon by Femtosecond Mid-infrared Laser Pulses

TL;DR

This study investigates how femtosecond mid-infrared laser pulses interact with silicon, revealing unique damage and ablation mechanisms driven by wavelength-dependent ponderomotive effects, which challenge existing models.

Contribution

It provides the first systematic experimental analysis of high-intensity MIR laser interactions with silicon, highlighting wavelength-dependent damage thresholds and proposing new energy deposition pathways.

Findings

Damage thresholds vary with wavelength

Traditional models do not match observed wavelength scaling

Ponderomotive energy effects may dominate energy absorption

Abstract

Although ultrafast laser materials processing has advanced at a breakneck pace over the last two decades, most applications have been developed with laser pulses at near-IR or visible wavelengths. Recent progress in mid-infrared (MIR) femtosecond laser source development may create novel capabilities for material processing. This is because, at high intensities required for such processing, wavelength tuning to longer wavelengths opens the pathway to a special regime of laser-solid interactions. Under these conditions, due to the ${\lambda}^2$ scaling, the ponderomotive energy of laser-driven electrons may significantly exceed photon energy, band gap and electron affinity and can dominantly drive absorption, resulting in a paradigm shift in the traditional concepts of ultrafast laser-solid interactions. Irreversible high-intensity ultrafast MIR laser-solid interactions are of primary interest in this connection, but they have not been systematically studied so far. To address this fundamental gap, we performed a detailed experimental investigation of high-intensity ultrafast modifications of silicon by single femtosecond MIR pulses (${\lambda}$ = 2.7 - 4.2 ${\mu}$m). Ultrafast melting, interaction with silicon-oxide surface layer, and ablation of the oxide and crystal surfaces were ex-situ characterized by scanning electron, atomic-force, and transmission electron microscopy combined with focused ion-beam milling, electron diffractometry, and ${\mu}$-Raman spectroscopy. Laser induced damage and ablation (LIDA) thresholds were measured as functions of laser wavelength. The traditional theoretical models did not reproduce the wavelength scaling of the damage thresholds. To address the disagreement, we discuss possible novel pathways of energy deposition driven by the ponderomotive energy and field effects characteristic of the MIR wavelength regime.