Overview
ABSTRACT
This paper deals with optical fibers, planar waveguides and microspheres made of fluoride glasses. Thermal, mechanical and optical (especially infrared) properties are detailed.
Techniques of elaboration of the three types of waveguides are presented.
Fluoride fibers are of interest for the following domains of application: spectrometry, astronomy, optical amplification, fiber lasers, and infrared supercontinuum sources.
Planar waveguides aims at application in integrated optics: optical amplifiers, compact lasers.
Microspheres are studied for microlasers applications and their potential as miniaturized optical memory.
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Read the articleAUTHORS
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Brigitte BOULARD: Senior Lecturer at the Institute of Molecules and Materials of Le Mans (IMMM) – Oxides and Fluorides Department, UMR CNRS 6283 (Le Mans University, France)
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Jean-Luc ADAM: CNRS Research Director Institut des sciences chimiques de Rennes (ISCR), Glass and Ceramics Team, UMR CNRS 6226 (University of Rennes I, France)
INTRODUCTION
The fluoride glasses discussed in this article are zirconium, indium/gallium or aluminum fluoride glasses, with the exception of beryllium fluoride glasses, which have been known for decades but are unusable in practice due to their hygroscopicity and toxicity.
The discovery of zirconium fluoride-based lenses in the 1970s, on the other hand, led to numerous technological developments in the field of optics.
Fluoride glasses are characterized by an infrared transmission limit shifted by several μm towards longer wavelengths, compared with the reference glass, silica. This characteristic lowers the minimum attenuation of fluoride fibers by an order of magnitude compared with silica, in theory.
In practice, despite the considerable resources deployed worldwide by laboratories and companies to improve the chemical purity of fluoride glasses, this very low level of optical loss has never been achieved.
While fluoride glasses can't compete with silica in terms of losses, and therefore in terms of long-distance transmission for telecommunications, they are unavoidable in the field of doped earth-rare laser fibers.
The infrared transmission limit is directly related to the fundamental frequencies of vibration between the elements making up the glass. These frequencies, or phonon energies, are about a factor of 2 lower in fluoride glasses than in oxides.
The result is a very significant reduction in non-radiative processes, and therefore a remarkable increase in the luminescence quantum yields of rare-earth ions in fluorides.
Fluoride glasses are widely used in the form of laser fibers emitting at wavelengths ranging from visible to mid-infrared, using various rare-earth ion dopings. Undoped, fluoride glass fibers are also used for infrared signal transmission (optical losses from 2 to 30 dB/km and mechanical strength from 50 to 500 kpsi).
Other types of waveguide, such as confined planar waveguides for integrated optics and microspheres, are also being extensively studied.
The aim of this article is to review the state of the art in fluoride glass optical waveguides, starting with the fundamentals of glass chemical formulations and their physical properties, essentially thermal, mechanical and optical. It also describes the techniques used to produce different types of waveguides: fibers, planar guides and microspheres.
As far as possible, the article situates the properties of fluorinated glasses and waveguides in relation to those of better-known silica-based glasses. This is particularly true of infrared transmission, luminescence and laser emission properties, in connection...
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KEYWORDS
optical fiber | infrared | waveguide | laser | planar waveguide | microsphere | laser fiber | fluoride glass
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OHANA' project – Optical Hawaiian Array for Nanoradian Astronomy https://tel.archives-ouvertes.fr/tel-01084792/document
GRAVITY program – General Relativity Analysis via Vet In Terferometry http://lesia.obspm.fr
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Fluoride Glass – Fluoride Glass Experts http://leverrefluore.com/
Thorlabs Inc – Your source for Fiber Optics https://www.thorlabs.com/
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