Thin-film optics: Difference between revisions
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morpho and peacock iridescence is formed by more complicated periodic structures, not simply planar layers; link photonic crystal |
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[[Image:Dichroics.jpg|thumb|right|300px|Dichroic filters are created using thin film optics.]] |
[[Image:Dichroics.jpg|thumb|right|300px|Dichroic filters are created using thin film optics.]] |
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'''Thin-film optics''' is the branch of [[optic]]s which deals with very thin structured layers of different materials. In order to exhibit thin-film optics, the thickness of the layers of material must be on the order of the wavelengths of visible light (about 500 [[nanometre|nm]]). Layers at this scale can have remarkable reflective properties due to light wave [[interference]] and the difference in [[refractive index]] between the layers, the air, and the substrate. These effects alter the way the optic [[Reflection (physics)|reflects]] and [[transmission (telecommunications)|transmits]] light. You can observe these effects every day in [[soap bubble]]s and oil slicks. |
'''Thin-film optics''' is the branch of [[optic]]s which deals with very thin structured layers of different materials. In order to exhibit thin-film optics, the thickness of the layers of material must be on the order of the wavelengths of visible light (about 500 [[nanometre|nm]]). Layers at this scale can have remarkable reflective properties due to light wave [[interference]] and the difference in [[refractive index]] between the layers, the air, and the substrate. These effects alter the way the optic [[Reflection (physics)|reflects]] and [[transmission (telecommunications)|transmits]] light. You can observe these effects every day in [[soap bubble]]s and oil slicks. |
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More general periodic structures, not limited to planar layers, are known as [[photonic crystal]]s |
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In manufacturing, thin film layers can be achieved through the [[Thin-film deposition|deposition]] of one or more thin layers of material onto a substrate (usually [[glass]]), most often by a [[physical vapor deposition]] process such as evaporative or [[sputtering]], or a chemical process such as [[chemical vapor deposition]]. These thin films are used to create [[optical coating]]s. |
In manufacturing, thin film layers can be achieved through the [[Thin-film deposition|deposition]] of one or more thin layers of material onto a substrate (usually [[glass]]), most often by a [[physical vapor deposition]] process such as evaporative or [[sputtering]], or a chemical process such as [[chemical vapor deposition]]. These thin films are used to create [[optical coating]]s. |
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This process is used to create low-emissivity panes of [[glass]] for houses and cars, [[anti-reflective coating]]s on [[glasses]], reflective baffles on car headlights, and for high precision [[filter (optics)|optical filters]] and [[mirror]]s. |
This process is used to create low-emissivity panes of [[glass]] for houses and cars, [[anti-reflective coating]]s on [[glasses]], reflective baffles on car headlights, and for high precision [[filter (optics)|optical filters]] and [[mirror]]s. |
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Thin-film layers are common in the natural world. Their effects produce colors seen in soap bubbles and oil slicks, as well as in many branches of the animal kingdom. For example |
Thin-film layers are common in the natural world. Their effects produce colors seen in soap bubbles and oil slicks, as well as in many branches of the animal kingdom. For example, the light collecting ''[[tapetum lucidum]]'' of many nocturnal species and the [[photophore]]s of [[Bioluminescence|bioluminescent]] squid (e.g. the [[Bobtail squid]]). In many cases, iridescent colors that were once thought to result from planar layers, such as in [[opal]]s, [[peacock]]s, and the [[Blue Morpho]] butterfly, turn out to result from more complex periodic photonic-crystal structures. |
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== Further reading == |
== Further reading == |
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Revision as of 01:56, 30 May 2006
Thin-film optics is the branch of optics which deals with very thin structured layers of different materials. In order to exhibit thin-film optics, the thickness of the layers of material must be on the order of the wavelengths of visible light (about 500 nm). Layers at this scale can have remarkable reflective properties due to light wave interference and the difference in refractive index between the layers, the air, and the substrate. These effects alter the way the optic reflects and transmits light. You can observe these effects every day in soap bubbles and oil slicks.
More general periodic structures, not limited to planar layers, are known as photonic crystals
In manufacturing, thin film layers can be achieved through the deposition of one or more thin layers of material onto a substrate (usually glass), most often by a physical vapor deposition process such as evaporative or sputtering, or a chemical process such as chemical vapor deposition. These thin films are used to create optical coatings.
This process is used to create low-emissivity panes of glass for houses and cars, anti-reflective coatings on glasses, reflective baffles on car headlights, and for high precision optical filters and mirrors.
Thin-film layers are common in the natural world. Their effects produce colors seen in soap bubbles and oil slicks, as well as in many branches of the animal kingdom. For example, the light collecting tapetum lucidum of many nocturnal species and the photophores of bioluminescent squid (e.g. the Bobtail squid). In many cases, iridescent colors that were once thought to result from planar layers, such as in opals, peacocks, and the Blue Morpho butterfly, turn out to result from more complex periodic photonic-crystal structures.
Further reading
- M. F. Land (1972). The physics and biology of animal reflectors. Progress in Biophysics and Molecular Biology. 24:75-106. doi:10.1016/0079-6107(72)90004-1. An excellent introduction to thin-film optics, with a focus on biology. Cites more rigorous treatments.