Morphology Characterization and Refractive Index Analysis of Subsurface Ultrashort‐Pulsed Laser Modifications in ZnS

A parameter study of ultrashort pulse laser‐induced modifications in the bulk of ZnS crystals is reported. Experimental results on these modifications and their dependence on the pulse energy, writing speed, and depth are presented, with an emphasis on cross‐sectional morphology and induced refracti...

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Bibliographic Details
Published in:Physica status solidi. A, Applications and materials science Applications and materials science, 2024-09, Vol.221 (17), p.n/a
Main Authors: Einmo, Eskil, Tolstik, Nikolai, Grivas, Christos, Demesh, Maksim, Kontis, Paraskevas, Sorokina, Irina T., Di Sabatino, Marisa
Format: Article
Language:English
Subjects:
direct laser writing
II‐VI semiconductors
Laser beams
laser material processing
Lasers
Morphology
Parameter modification
Pulse duration
Pulsed lasers
quantitative phase microscopy
refractive index
Refractivity
Short pulses
subsurface laser‐induced material modifications
Zinc sulfide
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Summary:A parameter study of ultrashort pulse laser‐induced modifications in the bulk of ZnS crystals is reported. Experimental results on these modifications and their dependence on the pulse energy, writing speed, and depth are presented, with an emphasis on cross‐sectional morphology and induced refractive index changes. Localized permanent material modifications have been inscribed in the bulk of the crystal using a laser with a center emission wavelength of 2.09 μm and a pulse duration of ≈4 ps. The morphology strongly depends on the laser and optical focusing parameters, in particular, on the pulse energy and processing speed, with a significant shift in depth dependence for short pulse‐to‐pulse separations. Depending on the applied pulse energy, distortions of the lateral profile of the refractive index changes appear in the form of oscillatory features in the transverse plane relative to the inducing laser beam. The true extent of the modified material is revealed by the alternating lateral profile with largest induced negative refractive index change, Δn, of −3.88 × 10−2 ± 0.18. Such parametric insight is of critical importance for the understanding and optimization of the fabrication process and for realizing compact 3D photonic devices in the bulk of materials in a reproducible manner. Ultrashort pulsed laser‐induced modifications in the bulk of multicrystalline ZnS are realized and characterized. Their cross‐sectional morphology and refractive index profiles are found to highly depend on the laser setup parameters. Such parametric insight is crucial for realizing compact subsurface 3D geometries for photonic applications.
ISSN:1862-6300
1862-6319
DOI:10.1002/pssa.202400299