Background:
Metallic–dielectric plasmonic nanoparticles have recently aroused great interest
in view of many and novel technological applications, based on the interaction between light
and matter under intense field conditions, in nonlinear integrated photonics and opto-fluidics, thanks
to the possibility of tuning their electronic and optical properties through a fine control of the synthesis
parameters and their nanoparticles under a high-power laser, like the one used during z-scan measures.
Objective:
The goal of this work is the study of nonlinear optical properties (as nonlinear refraction,
scattering, two-photon absorption, optical limiting) of colloids synthesized in different liquid media by
Pulsed laser ablation in liquids (PLAL), which is a photo-assisted synthesis technique ensuring the
formation of stable, contaminant-free colloids directly during the ablation process.
Methods:
Noble metal nanoparticles, metal oxides hybrid nanostructures and silicon-based nanomaterials,
were prepared by nanosecond and picosecond PLAL technique, in different media. The
third-order nonlinear optical (NLO) properties have been studied by the use of a single beam z-scan
technique with Q-switched frequency doubled Nd:YAG laser (λ=532 nm) at 5 ns pulse.
Results:
1) A good stability of the PLAL nanocolloids under a high laser power; 2) the limiting
threshold reduction inducted by the Ag-Au nanoparticles, the increase of the NLO absorption coefficient
β, the reduction of the transmittance/scattering signal and the presence of a pronounced asymmetry
of the peak/valley profile of the metal decorated metal oxide nanomaterials compared to the
separately produced components.
Conclusion:
An intriguing coupling between the nature of the optical limiting response and the
nanostructures rearrangement upon intense field conditions, explaining z-scan data by a classical approach
able to account for the nanoparticles asymmetry and plasmonic effects, are the main results
found.
Synthesis, characterization and nonlinear optical properties of polylactide and PMMA based azophloxine nanocomposites for optical limiting applications
