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Reactive matrix clean-up of naturally occurring perylene in young lignite

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Abstract

Young lignite from two locations in Sendai City, Japan, were analyzed for polynuclear aromatic compounds (PACs). Lignite samples were extracted with toluene and PACs were isolated by a compound-class-selective, reactive matrix clean-up. This clean-up separates all compounds of polynuclear aromatic structure, for example hydrocarbons and ketones and their primary metabolites, from interfering organic compounds. The result of this isolation procedure is, therefore, a group of a large number of polycyclic compounds with different functional groups. Further analysis is done by glass capillary gas chromatography. Perylene was identified as the only compound obtained by the reactive matrix clean-up of lignite samples from both locations. Concentrations were in the range of 1–10 mg kg−1. Conversely, PACs resulting from particulate emissions from fossil fuel combustion always contain isomeric PAHs (polynuclear aromatic hydrocarbons) with some polycyclic aromatic ketones and thousands of primary and secondary metabolites at very low concentrations. This was demonstrated for a sample of urban air particulate matter, which is the source of PAC contamination of surface soil. The absence of accompanying PAHs and polynuclear aromatic ketones in the lignite samples confirms that perylene did not originate from a combustion process. It is assumed that the high concentrations of perylene are the result of a reduction of perylene quinone. Thus, the high perylene content of the lignite samples investigated is of biogenic origin.

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  1. Environmental, Industrial, and Food Analysis, Postfach 1428, 38334, Helmstedt, Germany

    Torsten Spitzer

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  1. Torsten Spitzer
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Correspondence to Torsten Spitzer.

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Spitzer, T. Reactive matrix clean-up of naturally occurring perylene in young lignite. Anal Bioanal Chem 391, 2923–2929 (2008). https://doi.org/10.1007/s00216-008-2219-1

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  • DOI: https://doi.org/10.1007/s00216-008-2219-1

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