Improvement of the optical and morphological properties of microlens arrays fabricated by laser using a sol–gel coating

•Microlens arrays were fabricated on soda-lime glass using a Ti:Sapphire laser.•A SiO2 coating prepared via sol–gel route was used to improve the microlens quality.•The sol–gel coating was deposited at the microlens top surface using a dip coating.•Optical properties of the microlenses were improved...

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Bibliographic Details
Published in:Applied surface science 2015-10, Vol.351, p.697-703
Main Authors: Nieto, Daniel, Gómez-Varela, Ana Isabel, Martín, Yolanda Castro, O’Connor, Gerard M., Flores-Arias, María Teresa
Format: Article
Language:English
Subjects:
Arrays
Coating
Deposition
Laser ablation
Laser microfabrication
Lasers
Microlens arrays
Microlenses
Optical properties
Silicon dioxide
Soda-lime glass
Sol gel process
Sol–gel coating
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Summary:•Microlens arrays were fabricated on soda-lime glass using a Ti:Sapphire laser.•A SiO2 coating prepared via sol–gel route was used to improve the microlens quality.•The sol–gel coating was deposited at the microlens top surface using a dip coating.•Optical properties of the microlenses were improved by the coating. We present a simple, repeatable and non-contaminant method to improve the optical and morphological properties of microlens arrays. It consists on depositing hybrid SiO2 (TEOS, MTES) coatings via sol–gel route onto microlens arrays fabricated using a Ti:Sapphire Femtosecond Amplitude Systems S-pulse HP laser operating at 1030nm. The deposited silica sol–gel layer reduces the surface roughness (quantified as the root mean square) and increases the quality of the interstices between the microlenses generated by the ablation process, thus improving the contrast and homogeneity of the foci of the microlens array. The proposed technique allows us to obtain microlenses with a diameter in the range of 15–20μm and a depth of 1.5–15μm. For the characterization of the micro-optical structures, the UV–visible spectroscopy, spectral ellipsometry, confocal microscopy and beam profilometry were used. The proof-of-principle presented in this paper can be used to improve the optical and morphological properties of micro-optical systems of different nature by tailoring the parameters involved in both the laser ablation and sol–gel processes comprising the starting materials, solvent and catalysts nature and concentration, hydrolysis ratio, aging time and/or deposition conditions.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2015.05.177