Optical Tests of Nanoengineered Liquid Mirrors

We describe a new technology for the fabrication of inexpensive high-quality mirrors. We begin by chemically producing a large number of metallic nanoparticles coated with organic ligands. The particles are then spread on a liquid substrate where they self-assemble to give optical quality reflective...

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Bibliographic Details
Published in:arXiv.org 2003-01
Main Authors: Yockell-Lelievre, Helene, Borra, Ermanno F, Ritcey, Anna, Lande Vieira da Silva Jr
Format: Article
Language:English
Subjects:
Balances (scales)
Binoculars
Electromagnetic fields
Ferrofluids
Liquid mirrors
Liquid surfaces
Nanoparticles
New technology
Optical components
Organic chemistry
Reflectance
Substrates
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Summary:We describe a new technology for the fabrication of inexpensive high-quality mirrors. We begin by chemically producing a large number of metallic nanoparticles coated with organic ligands. The particles are then spread on a liquid substrate where they self-assemble to give optical quality reflective surfaces. Since liquid surfaces can be modified with a variety of means (e.g. rotation, electromagnetic fields), this opens the possibility of making a new class of versatile and inexpensive optical elements that can have complex shapes which can be modified within short time scales. Interferometric measurements show optical quality surfaces. We have obtained reflectivity curves that show 80% peak reflectivities.We are confident that we can improve the reflectivity curves, for theoretical models predict higher values. We expect that nanoengineered liquid mirrors should be useful for scientific and engineering applications. The technology is interesting for large optics, such as large rotating parabolic mirrors, because of its low cost. Furthermore, because the surfaces of ferrofluids can be shaped with magnetic fields, one can generate complex, time varying surfaces difficult to make with conventional techniques.
ISSN:2331-8422
DOI:10.48550/arxiv.0301053