SU790970A1 - Method of determination of dispersed substance relative difraction factor integral part - Google Patents

Description

the angle at which it is equal to zero is determined, and the real part of the relative refractive index of the matter of the particles is determined from the magnitude of this angle.

FIG. 1 shows the calibration curve; in fig. 2 d - the dependence of p-1) on the angle of scattering, at which the element of the scattering matrix f ,, 3 changes its sign to the opposite.

The method is carried out as follows.

Pre-spherical erythrocytes, which are a polydisperse medium with the most probable particle radius, equal to r ,, 2,4t3,4 µm, the relative half-width of the distribution function with respect to MejDaM dG || 0, 85 and the imaginary part of the complex index of refraction; U 4 10, are illuminated with light, polarized at an angle of 45 ° to the plane of incidence, and an emission wavelength of 0 0.546 µm. For scattering angles of 80 ° and thirds, thirds are measured on the polarization nephelometer1 | Stokes parameter 3450. where 3 - the measured intensity / indices from below refer to the state of polarization of the source, from above - to the state of polarization of the receiver. Next, the polarization of the incident radiation is changed to orthogonal and the measurements are repeated, the scattering matrix element is calculated -f / 2 (545 - according to the graph (Fig. 2) the angle is determined at which it is zero and the calibration curve (Fig. 1) determine the real part of the relative refractive index of the dispersed substance.

To ensure the conditions of applicability of the method, lecithin is preliminarily added to the blood, whereupon the erythrocytes from the discs turn into spheres of equivalent volume and are diluted 1000 times in physiological saline. Measurements are made at pH 7, OV7.4; t 18t22 ° C in a cuvette, 5 cm thick. When these conditions are met, dg / gd does not change for 1-2 hours, and the time required for measurements does not exceed 15 minutes.

As can be seen from FIG. 2, the angle at which the element of the matrix fj O is equal to WT. This corresponds to a value of Dg (n-1) of 0.055 and a relative refractive index of erythrocytes in saline at X 0.546 µm, n of 1.055, which, within the measurement error, coincides with the values of the refractive index obtained by another method.

When constructing the calibration graph (Fig. 1), the matrix element fjj was calculated on the Minsk-22 computer with the parameters previously indicated. Due to the fact that, when measuring, it is important that the angle at which the matrix element changes its sign to the opposite, and the absolute value of the scattering intensity does not play a significant role, while maintaining the condition of single scattering, the red blood cell concentration in the cell can change. relatively wide limits.

The use of the present invention makes it possible to quickly determine the real part of the relative refractive index of polydisperse hydrosols with an error cG (Di) / di: 15% in absorbing and non-absorbing media for values of 3t from O to.

The invention of mocket is widely used in medical and biological research, as well as for the angles of optical constants of hydrosols.

Claims (1)

Invention Formula The method of determining the real part of the relative refractive index of dispersed substances by measuring the intensity of scattered radiation, characterized in that in order to determine the refractive index of polydisperse spherical particles in the range from 1.02 to 1.07, the suspension of particles is illuminated by light polarized at an angle of + 45 ° to the plane of incidence, the third Stokes parameter is measured at three the scattering angles are not in the interval 80t120 and then illuminate with light polarized at an angle of -45, and again measure the measurements, calculate the scattering matrix element, determine the angle at which it is zero, and determine the real part of the relative refractive index of the particle matter from the angle. Sources of information taken into account in the examination 0 1. Naumenko E...K., Prishivgshko A.P. Investigation of the sensitivity of the attenuation coefficients to changes in optical constant particles in a polydisperse medium. e Journal of Applied Spectroscopy. V. 3, issue. XIV, 1971, p. 494-501. 2, N.I. Dudo Prishivalko A.P. On the optimal conditions for determining the coefficient of green matter ± w of particles by the angular characteristics of the light scattered by them. Journal of Applied Spectroscopy. V. 3, issue. 25, p. 504-511, 1976 (prototype). f, pa9 w 9f M2 Avz 0.04 ao5 atv cri A. / 3J P "if y 60 90 t VVG, “A