SU1712329A1 - Ir-transparent glass - Google Patents

Abstract

The invention relates to glasses that are transparent in the infrared region of the spectrum. In order to increase the refractive index and lower the temperature, softer glass has the following composition, mol%: ZrF ^ 30-65; SnF2 35-70. Glass has a refractive index of 1,599-1,698. softening temperature 78-200 ° C. 1 tab.

Description

The invention relates to optical fluoride glasses / transparent in the infrared region of the spectrum, which are promising materials for IR fiber optics and can be used as a material for both the core and the cladding of optical fibers.

The aim of the invention is to increase the refractive index and lower the temperature of the softening.

Glass, including zirconium tetrafluoride, additionally contains tin difluoride in the following ratio of components: mol.% 2gP4 30-65%, SnF2 35-70%.

At the indicated ratios of the source components, optical glasses having a transmission range of 0.2 to 7.5 µm are obtained. Going beyond the ratios proposed leads to the formation of a mixture of crystalline and glassy phases.

The glass is synthesized by melting the mixture in a platinum beaker with an inner diameter of 35 mm in an electric furnace at 400 ° C for 25-30 minutes, after which the melt is poured into the cooled Nickel form. The mixture is prepared by thoroughly mixing the appropriate quantities of the listed metal fluorides: tin and zirconium of the OFS brand. All operations are carried out in a dry box,

PRI me R 1. Take 13.3 K (65 mol.%) GgP4. 6.7 g (35 mol.%) SnF2 brand OCh, mix thoroughly and load into a hermetically sealed platinum cup. Melted at 400 ° C and held for 25 minutes. The melt is cooled in an oven to 300 ° C and poured into the cooled form. All operations are carried out in a dry box. The obtained sample does not contain visible crystalline inclusions, X-ray amorphous. The refractive index of glass, (n) ,. measured by the immersion method, is equal to n "1,599. The accuracy of the method is 0.003.

Examples 2-5 are carried out in the same manner as Example 1. The specific composition of the charge and

the characteristics of the obtained glasses are given in the table.

As can be seen from the table, glasses obtained within the limits of the concentrations indicated in the claims have lower melting points (examples 1-5) and a higher refractive index as compared to glass of known composition. On leaving the limits of the interval, a mixture of crystalline and amorphous phases is obtained - sitall (examples 6-7).

These advantages of glasses allow the IR fibers to be drawn out of plastic in a polymer shell that protects the glass from exposure to the atmosphere during the drawing process. A significant change in the refractive index in the field of glass formation allows the use of glass to create elements of gradient optics, as well as both the core and the shell of a core with a significant

aperture. So, in the case of examples 1 and 4, an aperture value of 0.5 can be obtained. Values are calculated using the formula: / P1 P2, where u is the shell refractive index. In addition, the proposed technical solution drives 1 / t to simplify the system and reduces the possibility of contamination of the glasses with impurities, since the system is two-component.

Claims (1)

Invention Formula The glass is transparent in the PC spectral region, including ZrF, characterized in that, in order to increase the refractive index and decrease the softening temperature, it additionally contains SnFa in the following ratio of components, mol.%: ZrF430-65 SnPa35-70.