AI Article Synopsis
- - The study developed a multidimensional gas chromatography/mass spectrometry (MDGC/MS) system to analyze oxygenate compounds and BTEX in gasoline, utilizing a unique Deans switch system for effective sample transfer.
- - Researchers successfully conducted 12 heart-cut transfers of 20 compounds from one column to another to resolve overlapping signals, ensuring accurate quantification and identification using a fast-scanning mass analyzer.
- - The new method was validated and showed strong agreement with established testing methods for benzene and related compounds, confirming its reliability for assessing fuel quality as per European and American standards.
Article Abstract
In the present work, carried out in relation to the European and American Directives on the quality of petrol and diesel fuels, the simultaneous determination of the oxygenate compounds and BTEX in gasoline was achieved through the use of a multidimensional GC (MDGC)/MS system, employing a Deans switch-based transfer system, with an innovative configuration; the latter enabled multiple heart-cut transfers with no hint of retention time shift, a phenomenon that can occur in MDGC, providing the possibility to achieve more then 20 different heart-cuts for the compounds of interest. In this study, 20 selected compounds were quantitatively transferred with 12 heart-cuts, from a first to a secondary column, in order to resolve primary column co-elutions. Analyte quantification and identification was achieved through a fast-scanning quadrupole mass analyzer, operated in full scan mode, in order to evaluate also the interfering compounds transferred together with the compounds of interest. The multidimensional method developed was subjected to validation. All attained data were in excellent correlation with results obtained through the UNI-EN 12177:2000, ASTM D 5580-02 and ASTM D 4815-04 MDGC methods, for the determination of benzene, BTEX and oxygenate compounds in gasoline, respectively.
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| http://dx.doi.org/10.1002/jssc.200900577 | DOI Listing |
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