Mercury is one of the most harmful elements present in the Earth, and has both natural and anthropological sources. Moreover, Hg can undergo to many different transformation pathways during its biogeochemical, or industrial, cycles which in general involve redox reaction, both abiotic and biotic, and phase changes (1). Despite the toxicity of this pollutant, there is still a lack in the knowledge about the biogeochemistry of mercury in the ecosystem and, therefore, it is of utmost relevance to develop new scientific approaches to understand its transformation mechanisms and to identify its contamination sources. In this context, the determination of mercury stable isotopes ratios and, in particular, the identification of fractionation processes seems to be an extremely interesting and challenging application to verify the “provenance” of the element. Mercury, in fact, undergoes to both mass dependant, MDF, and mass independent fractionation, MIF, processes. In particular the MIF, involving only the odd isotopes (199Hg and 201Hg), appears to be a characteristic fingerprint of the process and the pathways involved in the Hg transformations (2). Thus, the study of both fractionation phenomena can be a powerful tool to identify its natural or anthropogenic source. This approach can be useful in case of polluted areas where many are the contamination sources in order to plan an environmental requalification. An intriguing case study is represented from the National Interest Site of the lagoon of Marano-Grado (Trieste, Italy), which is object of the present study. For these purposes, the evaluation of the isotopic composition in samples coming from this area has been performed by means of an HR-MC-ICP/MS system for the simultaneous determination of all the isotopes of interest (3). Due to the difficulties of the mercury ICP determination and the high number of the acquisition parameters the optimization and the validation of the analytical procedure was required, in order to obtain highly accurate and precise data. After this first step the method has been applied for the determination of the Hg isotopic fingerprints in environmental samples (e.g. sediments) coming from the Marano-Grado area. (1) W. Fitzgerald, C. Lamborg, Treatise on Geochemistry 9, Elsevier, 2004. (2) B. Bergquist, J. Blum, Elements, (2010), 353-357. (3) D. Foucher, H. Hintelmann, Anal. Bioanal. Chem., (2006), 1470-1478.
MERCURY ISOTOPE RATIOS AS CONTAMINATION MARKERS: PROCEDURE DEVELOPMENT AND APPLICATIONS / Baschieri, Carlo; Durante, Caterina; Marchetti, Andrea; Berni, Alex; Bertacchini, Lucia; Stefanocovelli, ; Petrini, Riccardo; Emili, Andrea; Tassi, Lorenzo. - In: EMIRATES JOURNAL OF FOOD AND AGRICULTURE. - ISSN 2079-052X. - STAMPA. - 24:(2012), pp. 13-13. (Intervento presentato al convegno Food, Functional Food and Nutraceuticals tenutosi a Ischia nel 3-7 Giugno 2012).
MERCURY ISOTOPE RATIOS AS CONTAMINATION MARKERS: PROCEDURE DEVELOPMENT AND APPLICATIONS
BASCHIERI, CARLO;DURANTE, Caterina;MARCHETTI, Andrea;BERNI, ALEX;BERTACCHINI, LUCIA;TASSI, Lorenzo
2012
Abstract
Mercury is one of the most harmful elements present in the Earth, and has both natural and anthropological sources. Moreover, Hg can undergo to many different transformation pathways during its biogeochemical, or industrial, cycles which in general involve redox reaction, both abiotic and biotic, and phase changes (1). Despite the toxicity of this pollutant, there is still a lack in the knowledge about the biogeochemistry of mercury in the ecosystem and, therefore, it is of utmost relevance to develop new scientific approaches to understand its transformation mechanisms and to identify its contamination sources. In this context, the determination of mercury stable isotopes ratios and, in particular, the identification of fractionation processes seems to be an extremely interesting and challenging application to verify the “provenance” of the element. Mercury, in fact, undergoes to both mass dependant, MDF, and mass independent fractionation, MIF, processes. In particular the MIF, involving only the odd isotopes (199Hg and 201Hg), appears to be a characteristic fingerprint of the process and the pathways involved in the Hg transformations (2). Thus, the study of both fractionation phenomena can be a powerful tool to identify its natural or anthropogenic source. This approach can be useful in case of polluted areas where many are the contamination sources in order to plan an environmental requalification. An intriguing case study is represented from the National Interest Site of the lagoon of Marano-Grado (Trieste, Italy), which is object of the present study. For these purposes, the evaluation of the isotopic composition in samples coming from this area has been performed by means of an HR-MC-ICP/MS system for the simultaneous determination of all the isotopes of interest (3). Due to the difficulties of the mercury ICP determination and the high number of the acquisition parameters the optimization and the validation of the analytical procedure was required, in order to obtain highly accurate and precise data. After this first step the method has been applied for the determination of the Hg isotopic fingerprints in environmental samples (e.g. sediments) coming from the Marano-Grado area. (1) W. Fitzgerald, C. Lamborg, Treatise on Geochemistry 9, Elsevier, 2004. (2) B. Bergquist, J. Blum, Elements, (2010), 353-357. (3) D. Foucher, H. Hintelmann, Anal. Bioanal. Chem., (2006), 1470-1478.
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