In this way the separaion can be performed under optimum carrier gas conditions while simultaneously the detector will generate an optimum signal-to-noise ratio. It is only added the moment the carrier gas leaves the column. Detection in GC remains unique in analytical chemistry because of the large number of customized detectors. But using it effectively means understanding the tradeoffs between selectivity, ease of use, and sensitivity. In other words: make-up gas does not play a role in the chromatographic process in the column. The electron capture detector (ECD) for GC is still used relatively unmodified today. In this particular case the function of the make-up gas is not to provide more gas but to improve the detector ionisation yield. An electron capture detector ( ECD) is a device for detecting atoms and molecules in a gas through the attachment of electrons via electron capture ionization. If helium is preferred as carrier gas for the column, simply using a make-up gas such as nitrogen or argon/methane will generate the expected detector sensitivity. Today, nitrogen (cheaper and universal) is often used as make-up gas for an ECD instead of the more specific argon/methane. Science Astronomy and Astrophysics (AP) Biochemistry (BC) Ecological Sciences (ES) High Energy Physics (HE) Inorganic and Physical Chemistry (IP). Methane reduces the electron energy by collision without ionizing the methane and avoids interference effects such as component ionization. For this reason some percentage of methane (5%) is added to the make-up gas argon (the most sensitive gas for an ECD regarding its ionizing capability). This can be achieved by introducing an inert gas into the ECD cell that collides with the rapid electrons and in that way slowing them down. Abstract: The objective of this thesis is to expand the utility of the photodetachment-modulated electron capture detector (PDM-ECD) for the study of gas-phase. The electrons emitted by the radioactive foil move too fast to be captured by the analyte molecules. This explains why the (linear) dynamic range of the ECD is often limited.Īctually, the mechanism of operation of the ECD is slightly more complex. Since it concerns very small holes, the background current should not be too high. This change in the background current is registered as 'holes' in the background. When there are electro-negative components present in the carrier gas, the background current is reduced because these components capture electrons. A current is produced between two electrodes in the detector supplied with a potential difference and this is monitored as a continuous background current. The electron capture detector (ECD) is a selective detector for electro-negative compounds, especially halogens.Ī (beta-ray) radio active source which can ionize the carrier gas is located in the detector.
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