SU1636694A1 - Gas discharge source for atomic absorption spectroscopy - Google Patents

Abstract

The invention relates to spectral light sources designed to work in atomic absorption spectrophotometers. The aim of the invention is to increase the stability of the radiation intensity of the resonance lines. The lamp contains a flask with a flat window, an anode 3 and a hollow cathode 4 whose discharge cavity is designed as a stepped cylinder. The diameters of the cross-section of the cylinder steps increase towards the exit

Description

The invention relates to spectral light sources for use in atomic absorption analysis equipment.

The purpose of the invention is to increase the stability of the intensity of the radiation of resonant lines.

The drawing shows a spectral lamp, a general view.

The lamp is a cylindrical glass flask 1 with a flat window 2 for the output of the radiation, transparent in the ultraviolet part of the spectrum. The anode 3 is made of nickel mark NP-2 in the form of a cylinder, a hollow cathode 4, the discharge cavity of which is made in the form of a stepped cylinder open on one side (at least two steps) with a gradually increasing diameter towards the radiation output. The cylindrical surfaces are smoothly interconnected. The surfaces of transition from one cylinder to another have the shape of a truncated cone. The lengths In and the diameters dn of the corresponding steps of the discharge cavity satisfy the conditions,, 65-0.95, Ki 1.0-2.5. The hollow cathode is installed in a glass tube 5 with a small gap between the inner glass tube and the lateral surface of the cathode, which is necessary to prevent the glow discharge from penetrating the lateral surface of the cathode. The cathode, the anode and the glass tube are mounted on the glass stem 6 using molybdenum leads 7. The anode lead inside the lamp for isolating from the gas discharge is placed in the glass tube 8, the lamp is filled with inert neon gas to the pressure calculated by the formula P dk A, where P is the gas pressure in the lamp; dk is the smallest diameter. The lamp is provided with an octal base 9 for a standard lamp panel for connecting to a power supply.

When such a lamp is connected to a power source between the anode 3 and the discharge cavity of the cathode 4, a glow discharge is ignited, ensuring the maximum current density, first in the cylinder stage, having

minimum diameter. Sputtered products in the form of neutral atoms enter the gas discharge, are excited there when they collide with electrons, and emit spectral lines, the radiation of which through the flat window 2 leaves the lamp.

B The initial period of lamp use is a glow discharge with a maximum current density in the cylinder stage that has a minimum diameter. As the lamp is used, as the pressure decreases, the discharge gradually moves to cylinders that have large diameters, thereby maintaining the conditions of the formula

Р-d А, providing a slower decrease in the intensity of the radiation of the resonance lines, which leads to an increase in the stability of the radiation intensity than in a lamp having an internal cavity of the cathode in the form of a cylinder of the same cross section along the entire length, where the optimum conditions P d occur with decreasing gas pressure A and a decrease in the intensity of radiation occurs more quickly.

Claims (1)

Invention Formula Spectral discharge lamp for atomic absorption made in the form of an inert gas-filled flask with a window for exit of radiation with an electrical insulating tube placed inside it, inside which an anode and a hollow cathode are located, and the pressure of inert gas P in the lamp satisfies the condition P d A, where d is the discharge diameter the cathode cavity, A is a constant coefficient depending on the type of gas, which, in order to increasing the stability of the intensity of radiation of resonant lines, the cathode cavity discharge is made in the form of a stepped cylinder without a base from the anode, the diameters of the n steps of which are related by the ratio dn, where di is the diameter of the first step of the anode from the anode,, 65-0.95 the step number, and the length of each step 1P is related to its diameter dn by the ratio ln Kidn, where, 0-2.5.