Source and distribution of pyrite and inorganic sulfur isotopes in the Saray and Pınarhisar Coalfields, North Thrace Basin, Turkey

This study is mainly concerned with sulfur isotope (δ34S) values of inorganic sulfur species associated with the North Thrace Basin's coals (Saray and Pınarhisar coalfields). Sulfur isotope analyses were performed on pyritic sulfur, native sulfur, sulfate sulfur (rozenite) and the precipitated...

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Bibliographic Details
Published in:International journal of coal geology 2020-07, Vol.227, p.103533, Article 103533
Main Authors: Erarslan, Cemile, Örgün, Yüksel, Balcı, Nurgul
Format: Article
Language:English
Subjects:
Coal
Marine sulfate
North Thrace Basin
Pyrite forms
Sulfur isotope
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Summary:This study is mainly concerned with sulfur isotope (δ34S) values of inorganic sulfur species associated with the North Thrace Basin's coals (Saray and Pınarhisar coalfields). Sulfur isotope analyses were performed on pyritic sulfur, native sulfur, sulfate sulfur (rozenite) and the precipitated sulfate (P-BaSO4) (leached sulfate from the coal). The δ34S values of pyritic sulfur, rozenite, native sulfur and P-BaSO4 samples in Saray coals ranging from −6.9‰ to −37.3‰ are comparable to the δ34S values of Pınarhisar coals which change from −1.1‰ to −59.3‰. A wide range of strong negative δ34S values in both coalfields, particularly in Pınarhisar site, indicate that bacterial sulfate reduction (BSR) and subsequent pyrite formation were the key processes in the peat depositional environments. As in the δ34S values of both coalfield sites, comparable Sr/Ba and Th/U ratios and pyrite forms (cleat filling and partly massive) of the coals imply that besides marine sulfate hydrothermal solutions, originated from volcanism being active during peat accumulation in the basin, also contributed to the sulfur pools in the coal depositional environments. Overall, the δ34S values of inorganic sulfur species, and the largest sulfur isotope fractionation between δ34S P-BaSO4 and the δ34Spyrite, obtained for the first time for the Thrace Coal Basin, suggest that bacterial reduction of sulfate, possibly marine and hydrothermally derived, and subsequent pyrite formation and its fast burial may have been contributed to sulfur budget in the basin. •Marine influence and bacterial sulfate reduction (BSR) was the main sulfur process in the peat depositional environment.•Both syngenetic and epigenetic pyrites are identified in the coalfield sites.•Sr/Ba and Th/U ratios of the coals indicate marine sulfate as main sulfur source for the coals.
ISSN:0166-5162
1872-7840
DOI:10.1016/j.coal.2020.103533