SU41718A1 - Polarizer - Google Patents

Description

Pre; The subject of the invention is a special device polarizer of light.

In the attached drawing of FIG. 1 depicts a polarizer; FIG. 2-modified form of polarizer; FIG. 3-6 are devices enabling to obtain a fully polarized beam.

The proposed polarizer consists of a plate cut from a duplicating body (in a uniaxial crystal parallel to the optical axis). Plate 1 is made Mayuva from one side and a matte surface is pressed against another transparent plate 3 (for example to glass) with a layer 2 of liquid immersion, the refractive index of which is equal to the refractive index of grist, for one of the beams - ordinary or extraordinary (Fig. 1). For this beam, the system is completely transparent, while the other (for which the refractive index of the liquid immersion is not equal to the refractive index in the crystal) on the matte a surface will be scattered. To enhance the effect, the polarizer can be assembled from two plates 3, oriented in the same way and folded with opaque surfaces with interlocking 4 immersion, or. 2)

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moreover, the middle plate is made matte on both sides, or of four plates, t, e. Such a polarizer and nicole are opaque in some one position and when the crystal is rotated 9Q ° the system becomes completely transparent | bye In the minimum position of light, the playinka of total darkness does not give, since the illuminated surface of the crystal is visible; if an ordinary beam is missed (for an extraordinary beam, the matte surface is much thicker, which is easy to see from the scattering stroke), then with several plates a considerable darkening is achieved. This disadvantage is avoided if there are lenses in the optical system containing such a polarizer. Indeed, for example, an image of an object in only one of the beams will be focused on a screen or photographic plate, and the light from the surface of the crystal itself, placed at the same time not in the focus of the optical system, will be scattered. You can also resort to the method of focal isolation (Fig. 3). Only a correctly assembled beam passes through the hole O in the opaque diaphragm D. Such a diaphragm may, for example, be placed in the tube of a polarization microscope after the objective.