SU837168A1 - Atomic absorbtion spectrophotometer - Google Patents

Description

(54) ATOMICALLY ABSORPTION SPECTROPHOTOMETER

The invention relates to the field of analytical instrumentation and can be used in the development of atomic absorption spectrophotometers.

Known atomic absorption spectrophotometers containing the source of the line spectrum, the atomizer of the sample and the recording device 1.

The disadvantage of such an atomic-absorptive spectrophotometer is a small luminosity.

The closest to the invention in technical essence and the achieved result is an atomic absorption spectrophotometer containing sequentially installed light source co. continuous radiation spectrum, the lighting system, the atomizer of the sample being analyzed, a beam splitter, a modulator, a spectral device and a recording device 2.

Its disadvantage is the low accuracy of the measurements, due to the impossibility of simultaneously taking into account the change in the intensity of the light source and non-selective absorption.

The purpose of the invention is to improve accuracy by simultaneously taking into account changes in the intensity of the light source and non-selective absorption.

This is achieved due to the fact that an additional atomizer with a constant concentration of the element being determined is installed in it between the modulator and the spectral instrument.

Using a spectral instrument, the spectral line of the element being determined is separated from the fluorescent radiation from the atomizer with a constant concentration of the element being detected, caused by the luminous flux, the direction of which is perpendicular to the optical axis of the spectral device, and the area of the spectral spectrum that falls into the spectral width of the slit other light flux, the direction of which coincides with the optical axis of the device. The intensity of the spectral line is proportional to the non-selective and selective absorption in the atomizer of the sample being analyzed, and the intensity of the portion of the flat spectrum to only non-selective absorption. At the output of the spectral instrument, a recording device is installed which allows the logarithm of the intensity ratio of the two light signals to be measured. Since both light fluxes are proportional to the intensity of the radiation source, the output signal will be determined only by selective absorption by the atoms of the element being detected.

The drawing shows a diagram of the proposed device.

The spectrophotometer consists of a source of light I with a continuous emission spectrum, focusing lenses 2, an atomizer 3 of the sample being analyzed, a beam-splitting mirror 4, rotating mirrors 5, a mechanical modulator 6, an atomizer 7 with a constant concentration of the detectable element, a spectral device 8 and a recording device 9 .

Atomic absorption spectrophotometer works as follows. The radiation from source 1 is directed by means of a focusing lens 2 to the atomizer 3, into which the sample to be analyzed is introduced. After that, the luminous flux is divided into two streams by means of the beam splitter mirror 4, which is modulated by a mechanical modulator 6. By means of rotating mirrors 5, mutually perpendicular streams are projected onto the atomizer 7, into which a solution of a detectable element with a constant concentration is introduced.

The fluorescent radiation in this atomizer, arising from the luminous flux, the direction of which is perpendicular to the optical axis of the spectral device 8, and the luminous flux, the direction of which coincides with the optical axis of the spectral device, is measured by a recording device 9.

A xenon arc lamp can be used as a source with a continuous emission spectrum. Atomizer can serve as a gas flame. As

spectral instrument can use a monochromator or multichannel spectrometer. The electronic recording circuit may be similar to the device used in dual-beam spectrophotometers.

The positive effect of the application of the invention is to reduce the analysis time, increase accuracy and

accuracy of measurement results, since when using an instrument constructed according to this scheme, it is not necessary to carry out the additional measurements necessary to take into account non-selective absorption and

measuring the intensity of the light source.

Claims (2)

1.Lvov B.V. Atomic absorption analysis. M., “Science, 1966, p. 136. 2. In the same place, pp. 141-143 (prototype). /