Fluoride glass

Fluoride glass is a class of non-oxide optical glasses composed of fluorides of various metals. Due to their low viscosity, it is very difficult to completely avoid the occurrence of any crystallization while processing it through the glass transition (or drawing the fiber from the melt).

Thus, although heavy metal fluoride glasses (HMFG) exhibit very low optical attenuation, they are not only difficult to manufacture, but are quite fragile, and have poor resistance to moisture and other environmental attacks.

Fluoride glasses' best attribute is that they lack the absorption band associated with the hydroxyl (OH) group (3200 – 3600 cm⁻¹) which is present in nearly all oxide-based glasses.^[1]

Properties

HMFG's were initially slated for optical fiber applications, because the intrinsic losses of a mid-IR fiber could in principle be lower than those of silica fibers, which are transparent only up to ~ 2 μm.

Such low losses were never realized in practice, and the fragility and high cost of fluoride fibers made them less than ideal as primary candidates. Later, the utility of fluoride fibers for various other applications was discovered.

These applications include mid-IR spectroscopy, fiber-optic sensors, thermometry, and imaging. Also, fluoride fibers can be used for guided lightwave transmission in media such as YAG (Yttrium aluminium garnet) lasers at 2.9 μm, as required for medical applications (e.g. ophthalmology and dentistry).^[2]^[3]

An example of a heavy metal fluoride glass is the ZBLAN glass group, composed of zirconium, barium, lanthanum, aluminum, and sodium fluorides. These materials' main technological application is as optical waveguides in planar and fibre form. They are advantageous especially in mid infrared (2000-5000 nm) range.^[4]

Production

Some fluoride glasses are difficult to produce on Earth due to their fast crystallization. The crystallization is slower in microgravity conditions.^[5]

Fluoride glass may also mean an oxide optical glass doped with zirconium fluoride.^[6]

A mix of fluoride glass and phosphate glass is fluorophosphate glass.

Fluoride glasses based on zirconium fluoride are a class of fluorozirconate glasses. ZBLAN glasses belong to this group as well.

Fluoride glasses based on aluminium fluoride are a class of fluoroaluminate glasses.

Doping praseodymium in fluoride glass allows it to be used as a single mode fiber optical amplifier (PDFA see also EDFA).

Optical elements made of calcium fluoride, namely of fluorite crystals, are used in some telephoto lenses, to correct color aberration. They are however being replaced with various low dispersion glasses, which have higher refraction index, better dimensional stability, and lower fragility.

References

↑ heavy-metal fluoride glass (glass), Britannica Online Encyclopedia
↑ Tran, D., et al., Heavy metal fluoride glasses and fibers: A review, J. Lightwave Technology, Vol. 2, p. 566 (1984)
↑ Nee, S.F., et al., Optical and surface properties of oxyfluoride glasses, Proc. SPIE, Vol. 4102, p. 122 (2000); Characterization of optical constants for transparent materials, in Properties and Characteristics of Optical Glass, Ed. A.J. Marker III, Proc. SPIE, Vol. 979, p. 62 (1988)
↑
↑ Glass from Space, NASA-supported researchers have discovered that glass formed in space has remarkable properties. April 14, 2003, Author: Karen Miller, Dr. Tony Phillips
↑ Definition of fluoride glass, iDigitalPhoto Dictionary

External links

RP Photonics: fluoride fibers

Glass science topics

Basics	Glass Glass transition Supercooling

Glass formulation	AgInSbTe Bioglass Borophosphosilicate glass Borosilicate glass Ceramic glaze Chalcogenide glass Cobalt glass Cranberry glass Crown glass Flint glass Fluorosilicate glass Fused quartz GeSbTe Gold ruby glass Lead glass Milk glass Phosphosilicate glass Photochromic lens glass Silicate glass Soda-lime glass Sodium hexametaphosphate Soluble glass Tellurite glass Ultra low expansion glass Uranium glass Vitreous enamel Wood's glass ZBLAN

Glass-ceramics	Bioactive glass CorningWare Glass-ceramic-to-metal seals Macor Zerodur

Glass preparation	Annealing Chemical vapor deposition Glass batch calculation Glass forming Glass melting Glass modeling Ion implantation Liquidus temperature Sol-gel technique Viscosity Vitrification

Optics	Achromat Dispersion Gradient-index optics Hydrogen darkening Optical amplifier Optical fiber Optical lens design Photochromic lens Photosensitive glass Refraction Transparent materials

Surface modification	Anti-reflective coating Chemically strengthened glass Corrosion Dealkalization DNA microarray Hydrogen darkening Insulated glazing Porous glass Self-cleaning glass Sol-gel technique Toughened glass

Diverse topics	Glass-coated wire Safety glass Glass databases Glass electrode Glass fiber reinforced concrete Glass ionomer cement Glass microspheres Glass-reinforced plastic Glass-to-metal seal Porous glass Prince Rupert's Drops Radioactive waste vitrification Windshield

Glass production techniques

Commercial techniques	Float glass process Blowing and pressing (containers) Extrusion / Drawing (fibers, glasswool) Drawing (optical fibers) Precision glass moulding Overflow downdraw method Pressing Casting Cutting Flame polishing Chemical polishing Diamond turning Rolling

Artistic and historic techniques	Beadmaking Blowing Blown plate Broad sheet Caneworking Crown glass Cylinder blown sheet Engraving Etching Fourcault process Fusing Lampworking Machine drawn cylinder sheet Millefiori Polished plate Slumping Stained glass fusing Stained glass production

Natural processes	Radiative processes Opal formation Sea glass Shock metamorphic glasses/Impactite Vitrified sand Volcanic glasses

See also	Glossary of glass art terms Glass recycling

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