Defect characterization in optical coatings using scattered light

Optical coatings play a vital role in sensing technologies. The development of new coatings that exhibit minimal optical losses requires a detailed understanding of the development of defects within them. Current methods of defect characterization involve direct microscope imaging or x-ray diffracti...

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Bibliographic Details
Published in:Applied optics. Optical technology and biomedical optics Vol. 62; no. 22; p. 6046
Main Authors: Loglia, Balthazar, Derrick, Emma, Ingraham, Luke, Fraser, Alexandra, Geng, Yutong, Sanger-Johnson, Grace, Colby, Kace, Kontos, Antonios
Format: Journal Article
Language:English
Published: 01.08.2023
ISSN:1539-4522, 1539-4522
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Summary:Optical coatings play a vital role in sensing technologies. The development of new coatings that exhibit minimal optical losses requires a detailed understanding of the development of defects within them. Current methods of defect characterization involve direct microscope imaging or x-ray diffraction studies in the case of crystallites. In this paper, we demonstrate the characterization of coating defects using light scattering, which can yield information about their size, location, and index of refraction. The method requires measuring the scattered power of each individual defect as a function of angle and comparing the data with theoretical models. Finally, we argue that this method can be used for the determination of the defect location within a multi-layer stack.Optical coatings play a vital role in sensing technologies. The development of new coatings that exhibit minimal optical losses requires a detailed understanding of the development of defects within them. Current methods of defect characterization involve direct microscope imaging or x-ray diffraction studies in the case of crystallites. In this paper, we demonstrate the characterization of coating defects using light scattering, which can yield information about their size, location, and index of refraction. The method requires measuring the scattered power of each individual defect as a function of angle and comparing the data with theoretical models. Finally, we argue that this method can be used for the determination of the defect location within a multi-layer stack.
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ISSN:1539-4522
1539-4522
DOI:10.1364/AO.496538