Chemical Mechanical Polishing of Zerodur ® Using Silica and Ceria Nanoparticles: Toward Ultra-Smooth Optical Surfaces.
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| Title: | Chemical Mechanical Polishing of Zerodur ® Using Silica and Ceria Nanoparticles: Toward Ultra-Smooth Optical Surfaces. |
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| Authors: | Bellahsene, Houda1 (AUTHOR), Sene, Saad1,2 (AUTHOR), Félix, Gautier1,3 (AUTHOR), Fabregue, Nicolas1 (AUTHOR), Marcos, Michel2 (AUTHOR), Uhart, Arnaud3 (AUTHOR), Dupin, Jean-Charles3 (AUTHOR), Oliviero, Erwan1 (AUTHOR), Larionova, Joulia1 (AUTHOR), Ferrari, Marc2 (AUTHOR) marc.ferrari@osupytheas.fr, Guari, Yannick1 (AUTHOR) yannick.guari@umontpellier.fr |
| Source: | Nanomaterials (2079-4991). Sep2025, Vol. 15 Issue 18, p1391. 29p. |
| Subjects: | Silica nanoparticles, Cerium oxides, Surface texture, Optical devices, Finishes & finishing, Optical glass, Optical coatings, Nanoparticles |
| Abstract: | This study investigates hyperpolishing of Zerodur® substrates via chemical-mechanical polishing (CMP) using silica (SiO2) and ceria (CeO2) nanoparticles as controlled nano-abrasives. A pre-polishing stress-mirror stage was combined with systematic use of nanoparticles of variable size to evaluate surface-state evolution via optical rugosimeter, HRSEM, cross-sectional HRTEM, and XPS. A set of hexagonal mirrors with a circumscribed diameter of 30 mm was polished for one hour with each nanoparticle type. All tested slurries significantly improved surface quality, with both the smallest (37 nm) and largest (209 nm) SiO2 particles achieving similar final roughness, though larger particles showed a slight performance advantage that could be offset by longer polishing with smaller particles. CeO2 nanoparticles (30 nm) produced even better process efficiency and surface finishes than 37 nm SiO2, demonstrating higher chemical-mechanical polishing efficiency with CeO2. Sequential polishing strategies, first with 209 nm SiO2, then with 37 nm SiO2 and 30 nm CeO2, also enhanced surface quality, confirming trends from single-particle trials. One of the most effective protocols was adapted and scaled up to 135 mm Zerodur® mirrors with spherical and plano geometries, representative of precision optical components. The strategic approach adopted to achieve a high-quality surface finish in a reduced processing time relies on the sequential use of nanoparticles acting as complementary nano-abrasives. Indeed, applying two hours of polishing with 209 nm SiO2 followed by two hours with 37 nm SiO2 yielded exceptional results, with area roughness (Sa) values of 1 Å for spherical and 0.9 Å for plano surfaces. These results demonstrate the capability of nanoparticle-assisted CMP to produce sub-nanometric surface finishes and offer a robust, scalable approach for high-end optical manufacturing. [ABSTRACT FROM AUTHOR] |
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| Database: | Engineering Source |
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| Abstract: | This study investigates hyperpolishing of Zerodur® substrates via chemical-mechanical polishing (CMP) using silica (SiO2) and ceria (CeO2) nanoparticles as controlled nano-abrasives. A pre-polishing stress-mirror stage was combined with systematic use of nanoparticles of variable size to evaluate surface-state evolution via optical rugosimeter, HRSEM, cross-sectional HRTEM, and XPS. A set of hexagonal mirrors with a circumscribed diameter of 30 mm was polished for one hour with each nanoparticle type. All tested slurries significantly improved surface quality, with both the smallest (37 nm) and largest (209 nm) SiO2 particles achieving similar final roughness, though larger particles showed a slight performance advantage that could be offset by longer polishing with smaller particles. CeO2 nanoparticles (30 nm) produced even better process efficiency and surface finishes than 37 nm SiO2, demonstrating higher chemical-mechanical polishing efficiency with CeO2. Sequential polishing strategies, first with 209 nm SiO2, then with 37 nm SiO2 and 30 nm CeO2, also enhanced surface quality, confirming trends from single-particle trials. One of the most effective protocols was adapted and scaled up to 135 mm Zerodur® mirrors with spherical and plano geometries, representative of precision optical components. The strategic approach adopted to achieve a high-quality surface finish in a reduced processing time relies on the sequential use of nanoparticles acting as complementary nano-abrasives. Indeed, applying two hours of polishing with 209 nm SiO2 followed by two hours with 37 nm SiO2 yielded exceptional results, with area roughness (Sa) values of 1 Å for spherical and 0.9 Å for plano surfaces. These results demonstrate the capability of nanoparticle-assisted CMP to produce sub-nanometric surface finishes and offer a robust, scalable approach for high-end optical manufacturing. [ABSTRACT FROM AUTHOR] |
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| ISSN: | 20794991 |
| DOI: | 10.3390/nano15181391 |
