Temporal modulation toward femtosecond laser-induced nonlinear ionization process

The temporal chirp of single femtosecond (fs) pulses will affect the laser-induced ionization process. By comparing the ripples induced by negatively and positively chirped pulses (NCPs and PCPs), the growth rate showed a significant difference, resulting in a depth inhomogeneity of up to 144%. A carrier density model tailored with temporal characteristics showed that NCPs could excite a higher peak carrier density, contributing to a highly efficient generation of surface plasmon polaritons (SPPs) and overall advancement of the ionization rate. Such distinction originates from their contrary incident spectrum sequences. Current work reveals that temporal chirp modulation can control the carrier density in ultrafast laser-matter interaction, which possibly brings an unusual acceleration for surface structure processing. (c) 2022 Optica Publishing Group

Automated summary

The temporal chirp of single femtosecond pulses has an impact on laser-induced ionization, and the ripples induced by negatively and positively chirped pulses show significant differences, leading to depth inhomogeneity. The carrier density model reveals that negatively chirped pulses can generate higher peak carrier density, resulting in the efficient generation of surface plasmon polaritons and overall advancement of ionization rate.