SU642650A1 - Electron-capturing detector - Google Patents

Description

The invention relates to gas chromatography and may find application in various fields of analytical technology. Electron capture detectors are known, which contain a chamber with electrodes located in it, one of which is a cathode made of radioactive material, and inputs for the entrance and exit of gases l. The closest technical solution to the present invention is an electron capture detector comprising an anode and a cathode made of radioactive material, a chamber and channels for input and output of carrier gas and additional purge gas 2. The known electron capture detectors have a small linear detection range and a low fast response associated with the large volume of the detector chamber. The purpose of the invention is to increase the linear range of detection. For this, part of the chamber of the proposed detector, adjacent to the anode, has an extension to the surface to its surface, and a channel for outputting gas is located at the place of the maximum narrower part of the chamber adjacent to the anode. The electron capture detector consists of a housing 1, an anode 2, a cathode 3, on the surface of which a radioactive source 4 is located, channels 5-7 for introducing a carrier gas, for introducing additional purge gas and outlet gas, respectively. The detector works as follows. The radioactive radiation source 4 ionizes the gas in the detector chamber. Under the action of an electric field, the electrons move to the anode 2 and, on their way, can be captured by analyte molecules, which are fed through channel 5. The resulting negative volume charge creates a counter-emf that reduces the detector current. Typically, electron capture detectors are non-linear, and with increasing analyte concentration, the detector's sensitivity decreases. Introduced in the proposed detector, the expansion of the chamber to the anode surface leads to an increase in the chargeability of the volume charge, and with an increase in the concentration of the analyte. This reduces the fall of Chuv. with an increase in the concentration of the analyte, i.e. - leads to an increase in the linear detection range.

The location of the gas output channel at the point of maximum narrowing of the part of the Chamber adjacent to the anode limits the sensitive volume of the detector to the volume of this part of the chamber. The speed of the detector increases.

Similar design solutions can be implemented not only in the detector with flat electrodes, but also with cylindrical and spherical ones.

Claims (2)

1. Electroelectric detector containing an anode and a cathode, made from radioactive material, a chamber and channels of the input and output carrier gas and an additional purge gas, characterized in that in order to increase the linear detection range, the part of the chamber adjacent to the anode has a shape that expands to its surface. 2, the detector according to claim 1, characterized in that the channel for the discharge of gases is located at the point of maximum narrowing of the chamber part adjacent to the anode. Sources of information taken into account in the examination 1. Brazhnikov V.V. Differential detectors for gas chromatography. M., Science, 1974, pp. 101-104. 2. In the same place 103,