SU1678786A1 - Glass - Google Patents

Abstract

The invention relates to the manufacture of optical oxide glasses, activated by semiconductor compounds, and intended for use as optical filters and elements of laser technology. In order to increase the steepness of the absorption boundary and narrow the transition region while maintaining the long-wavelength absorption edge in the near infrared region of the spectrum while ensuring that the glass is not sensitive to heat treatment, it contains, in wt.% S102, 72.61-74.36; Na20 10.69-16.06; Kao 0.01-7.57; CuJnS2 0.74-0.99; CaO 8.39-8.58. The length of the new wave absorption edge of glass is 1, Tm, the slope of the absorption boundary is 0.2870-0.6294, and the optical properties of the glass do not change during heat treatment at 650 ° C for 4 hours. 2 tab.

Description

The invention relates to the manufacture of optical oxide glasses, activated by semiconductor compounds, and intended for use as optical filters and elements of laser technology.

The aim of the invention is to increase the steepness of the absorption boundary and narrow the transition region while maintaining the long-wavelength absorption edge in the near infrared region of the spectrum while ensuring that the glass is insensitive to heat treatment.

Glass is synthesized by melting a mixture made from reagents: silica glass, sodium carbonate, potassium carbonate, calcium carbonate, semiconductor compound CulnSz, which are in a finely dispersed state.

gas-fired furnace at a maximum temperature of 1450 ± 10 ° C with an exposure time of 1 h under reducing conditions. Coal in an amount of 2.0 wt.% is introduced into the charge mixture to create a reducing environment. Glass melting is carried out on a cold plate, followed by annealing of the samples in a muffle electric furnace at 570 ± 5 ° C for 2 hours. The spectral characteristics are studied on samples in the form of polished plane-parallel plates 2 mm thick.

Table 1 shows specific examples of glass compositions, and Table 2 shows their properties.

The numerical value of the steepness of the absorption boundary determines the gender of the formula

K DAgr - ioo DAgr where D Dgr and D Agr - loo is the optical density of the glasses at the transmission boundary and at a wavelength less than 100 nm.

About 4 00 xl 00

After heat treatment at 650 ° C and a shutter speed of 4 hours, the steepness of the absorption boundary of the glasses does not change.

The glass is stained during the synthesis process and does not require additional heat treatment. The long wavelength edge of the absorption band is located in the infrared region.

The absorption margin of the proposed glass is a steep line. The wavelength corresponding to the beginning of the transparency region (Lp) is 1.1 µm, which makes it possible to produce filters of such a glass that cut radiation with a wavelength of 1.1 µm. At the same time, the transmission limit does not change during annealing and heat treatment (pickup), which indicates that the semiconductor compound remains in the microcrystalline state directly during the cooking process and remains unchanged during annealing and heat treatment.

Claims (1)

Thus, from the data presented in Table 2, it follows that the proposed glass, in comparison with the known, has a smaller transition region on the spectral curve and a steeper transmission boundary, which makes it possible to significantly improve the quality of manufactured products. The invention includes glass, including SiOa, NaaO, fcO, CulnSa, characterized in that, in order to increase the absorption edge and narrow the transition region while maintaining the long-wave absorption edge in the near infrared spectral region and at the same time ensuring its insensitivity to heat treatment, it additionally contains CO2 in the following ratio, wt.%: 5,027.61-74.36 NaaO10,69-16,06 K200.01-7.57 CulnS20,74-0,99 Sa.08.39-8.58 Table table 2