Abstract
Microbial biofilms preferentially colonized pyrite surfaces of black shale incubated in groundwater in the Newark Basin (northeastern United States) for 1 month. SEM observation revealed the co-occurrence of bacteria-shaped pits and secondary iron minerals on pyrite, which indicate biological involvement in pyrite weathering and secondary solid formation. Of the 24 16S rDNA sequences obtained from bacterial communities on pyrite, arsenopyrite and quartz sand, 22 belonged to the phylum proteobacteria, including 5 identified as β or ϵ-proteobacteria capable of oxidizing iron or sulfur, 16 identified as members of the Fe(III)-reducing Geobacteraceae in the δ-proteobacteria and one identified as the Fe(III)-reducing Ferribacterium. Results indicate that microbes play an essential role in the oxidation of iron sulfides (via direct contact and indirect pathways) and the reduction of iron oxides in pyrite-bearing substrata of a slightly acidic black shale aquifer.
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Acknowledgments
We would like to thank Pierre Lacombe for access to the NAWC field site and for providing the groundwater data, Michael Serfes for assistance in the field, and Elizabeth Garcia, Valentin Starovoytov, Jerry Delaney and Yun Li for help with phylogenetic analysis, biofilm microscopy, and thick section element analysis. This project was supported by a grant from the U.S. National Science Foundation's Geobiology and Low-Temperature Geochemistry Program and a Hatchgrant through the New Jersey Agricultural Experiment Station.