SU1543307A1 - Method of determining optical anisotropy of rocks - Google Patents

Abstract

The invention relates to geological and mineralogical methods of studying rocks and can be used to restore the dynamic environment of the formation and deformation of geological bodies, solving various structural and petrological problems. The aim of the invention is to simplify, improve the accuracy and speed of determination of the optical anisotropy of rocks. The essence of the method lies in an integrated polarization-optical study of mineral aggregates by measuring the intensity of light transmitted through a thin section of rock that is placed between the polarizer and the analyzer.

Description

The invention relates to geological and mineralogical methods for studying rock and can be used to restore the dynamic environment of the formation and deformation of geological bodies, solving various structural and petrological problems.

The purpose of the invention is to simplify, increase the accuracy and express speed of determining the optical anisotropy of rocks.

The method is carried out as follows.

A transparent cut of the standard thickness of the rock is placed on a turntable between parallel

polarizer and analyzer in a wide beam of monochromatic light. The intensity of the light IH transmitted through the polarizer - grinding - analyzer system at different positions of the turntable is measured. The same measurements were performed with the polarizer and the analyzer Ilt crossed. The graph of the dependence of the light intensities 1 "and 11, which came out of the polarizer-analyzer system, versus angle d, was plotted. turn shlifa. The values of the light intensities I и and IL for one revolution are calculated.

The predominant optical orientation of individuals in the aggregate is determined by the constructed dependence.

m

& 0

 The average birefringence of mineral individuals and the degree of optical anisotropy Q of the whole section are calculated using the formulas given.

The proposed method analyzed olivine xenoliths from helix xenoliths. In thin sections corresponding to different mutually perpendicular xenolith sections, jg is detected according to measured dependencies; optical anisotropy is limited, the degree of which was 155 + 0.025 in section, parallel to the elongation of xenolite and, 023 in section, perpendicular to the xenolite elongation. It is established that the maximum optically anisotropic xenolith section is oriented parallel to the xenolite elongation. The time to obtain this result was 30 minutes. The determination of the predominantly optical orientation of the same samples by a known method required 10 h.

The effectiveness of the proposed method consists in the greater reliability of 25 results of determining the optical anisotropy of mountain rocks with a significant reduction in labor costs.

the preferential optical orientation of individuals in thin sections is divided as the angular position of the maximum of dependence 1 (| on the angle of rotation, the average birefringence π of individuals in the section of thin section according to the formula

n U / ffd) V 2 (1) / 1.7 (1

and the integral value of the degree of optical anisotropy Q thin section by the formula

ax microns

-I x,

Where

L

d

radiation wavelength; thin section thickness; the mean values of the light transmitted through the system for one revolution of the thin section with, respectively, crossed and parallel to the polarizer and the analyzer;

Yu

Claims (1)

Invention Formula The method of determining the optical anisotropy of rocks with a multitude of individuals, is that a beam of light passes through a polarizer - grinding - analyzer system and measures the intensity of the light that came out of the system, so that that, in order to simplify, increase express speed and accuracy, a beam of light with a cross section equal to the section of a thin section is passed through the system and the intensity of the light coming out of the system is measured, respectively with parallel II, polarizer and . | (and when L. ii. g is crossed, with the analyzer at different angles of rotation of the section around the optical axis of the system, the preferential optical orientation of individuals in the section as the angular position of dependence maximum 1 is fixed (| on the angle of rotation of the birefringence of individuals) in the section section according to the formula n U / ffd) V 2 (1) / 1.7 (1 and the integral value of the degree of optical anisotropy Q thin section by the formula ax microns -I x, 25 to 30 Where L d t  “Vis-35 IWMM radiation wavelength; thin section thickness; the mean values of the light transmitted through the system for one revolution of the thin section with, respectively, crossed and parallel to the polarizer and the analyzer; the maximum and minimum values of the light intensity per revolution of one section, shifted by 5 ° relative to each other.