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Autori principali: O'Byrne, Martin, Kerzabi, Badre, Abbarchi, Marco, Lifschitz, Alejo, Zamora, Tony, Malgras, Victor, Gourdin, Anthony, Modaresialam, Mehrnaz, Grosso, David, Putero, Magali
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.13324
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author O'Byrne, Martin
Kerzabi, Badre
Abbarchi, Marco
Lifschitz, Alejo
Zamora, Tony
Malgras, Victor
Gourdin, Anthony
Modaresialam, Mehrnaz
Grosso, David
Putero, Magali
author_facet O'Byrne, Martin
Kerzabi, Badre
Abbarchi, Marco
Lifschitz, Alejo
Zamora, Tony
Malgras, Victor
Gourdin, Anthony
Modaresialam, Mehrnaz
Grosso, David
Putero, Magali
contents This work describes the elaboration of rutile titanium dioxide films with high refractive indices and low scattering by sol-gel process and controlled crystallization. The evolutions of the optical properties and crystalline structure of sol-gel processed titania coatings on fused silica were investigated for different thermal budgets of the annealing post-treatment using ellipsometry, spectrophotometry, X-ray diffraction and electronic microscopy. It reveals that anatase and rutile coatings with refractive indices of 2.5 and 2.7 can be prepared with associated optical loss of 0.5% and 1%, respectively, which are excellent compromise for applications in integrated photonics. These evolutions are associated to the thermally induced mass transfer and phase transitions occurring during thermal annealing that involves first the nucleation growth and sintering of anatase polyoriented nanocrystals, followed by the transformation into rutile polyoriented nanocrystals. Concomitantly, rutile crystals with (110) faces parallel to the surface consume surrounding anatase and rutile nanocrystals by diffusive sintering to yield micron-size rutile monocrystalline and monooriented platelets patchwork, exhibiting refractive index of 2.73 and 1.2% optical loss. The formation of these platelets is governed by surface energies and is responsible for the increase in optical loss.
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publishDate 2024
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spellingShingle Investigation of the anatase-to-rutile transition for TiO$_2$ sol-gel coatings with refractive index up to 2.7
O'Byrne, Martin
Kerzabi, Badre
Abbarchi, Marco
Lifschitz, Alejo
Zamora, Tony
Malgras, Victor
Gourdin, Anthony
Modaresialam, Mehrnaz
Grosso, David
Putero, Magali
Optics
This work describes the elaboration of rutile titanium dioxide films with high refractive indices and low scattering by sol-gel process and controlled crystallization. The evolutions of the optical properties and crystalline structure of sol-gel processed titania coatings on fused silica were investigated for different thermal budgets of the annealing post-treatment using ellipsometry, spectrophotometry, X-ray diffraction and electronic microscopy. It reveals that anatase and rutile coatings with refractive indices of 2.5 and 2.7 can be prepared with associated optical loss of 0.5% and 1%, respectively, which are excellent compromise for applications in integrated photonics. These evolutions are associated to the thermally induced mass transfer and phase transitions occurring during thermal annealing that involves first the nucleation growth and sintering of anatase polyoriented nanocrystals, followed by the transformation into rutile polyoriented nanocrystals. Concomitantly, rutile crystals with (110) faces parallel to the surface consume surrounding anatase and rutile nanocrystals by diffusive sintering to yield micron-size rutile monocrystalline and monooriented platelets patchwork, exhibiting refractive index of 2.73 and 1.2% optical loss. The formation of these platelets is governed by surface energies and is responsible for the increase in optical loss.
title Investigation of the anatase-to-rutile transition for TiO$_2$ sol-gel coatings with refractive index up to 2.7
topic Optics
url https://arxiv.org/abs/2410.13324