Optimization of fs-laser-induced voxels in nonlinear materials via over-correction of spherical aberration

In this Letter, over-correction of spherical aberration is used to counteract nonlinear effects such as Kerr self-focusing and plasma effects, resulting in more spherical and small-sized femtosecond laser-inscribed voxels within nonlinear materials. By strategically redirecting marginal focusing ray...

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Veröffentlicht in:	Optics letters 2024-12, Vol.49 (24), p.7048
Hauptverfasser:	Lapointe, Jerome, Pouliot, Samuel, Dupont, Albert, Guérineau, Théo, Gaulin, Joseph, Pelletier, Étienne, Delarosbil, Jean-Luc, Lafrenière-Greig, Jonathan, Olivier, Loïc, Gagnon, Stéphane, Messaddeq, Younes, Vallée, Réal
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Sprache:	eng
Schlagworte:	Aberration Elongated structure Lasers Silicon dioxide Spherical plasmas Waveguides
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creator	Lapointe, Jerome Pouliot, Samuel Dupont, Albert Guérineau, Théo Gaulin, Joseph Pelletier, Étienne Delarosbil, Jean-Luc Lafrenière-Greig, Jonathan Olivier, Loïc Gagnon, Stéphane Messaddeq, Younes Vallée, Réal
description	In this Letter, over-correction of spherical aberration is used to counteract nonlinear effects such as Kerr self-focusing and plasma effects, resulting in more spherical and small-sized femtosecond laser-inscribed voxels within nonlinear materials. By strategically redirecting marginal focusing rays toward the beginning of the laser modification zone, the induced plasma prevents any rays from causing a structural modification beyond this zone, irrespective of any focus elongation caused by nonlinear effects. The method has been effectively validated across a range of materials, including ZnS, ZnSe, BIG, GeS , and SiO . A significant outcome is the achievement of quasi-spherical and (sub-)micrometer voxels in highly nonlinear materials. These findings open avenues for single-mode active waveguides and high-resolution patterning within nonlinear materials. The experiments are performed using a microscope objective equipped with a correction collar, a widely available tool in laboratories, highlighting the potential and versatility of the technique.
doi_str_mv	10.1364/OL.542171
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subjects	Aberration Elongated structure Lasers Silicon dioxide Spherical plasmas Waveguides
title	Optimization of fs-laser-induced voxels in nonlinear materials via over-correction of spherical aberration
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