Department of Earth and Environmental Sciences, University of Waterloo, Waterloo, ON, Canada.
Geobiology. 2012 Nov;10(6):506-17. doi: 10.1111/j.1472-4669.2012.00341.x. Epub 2012 Aug 28.
In a methanogenic crude oil contaminated aquifer near Bemidji, Minnesota, the decrease in dissolved CH(4) concentrations along the groundwater flow path, along with the positive shift in δ(13) C(CH) (4) and negative shift in δ(13) C(DIC) , is indicative of microbially mediated CH(4) oxidation. Calculations of electron acceptor transport across the water table, through diffusion, recharge, and the entrapment and release of gas bubbles, suggest that these processes can account for at most 15% of the observed total reduced carbon oxidation, including CH(4) . In the anaerobic plume, the characteristic Fe(III)-reducing genus Geobacter was the most abundant of the microbial groups tested, and depletion of labile sediment iron is observed over time, confirming that reduced carbon oxidation coupled to iron reduction is an important process. Electron mass balance calculations suggest that organic carbon sources in the aquifer, BTEX and non-volatile dissolved organic carbon, are insufficient to account for the loss in sediment Fe(III), implying that CH(4) oxidation may also be related to Fe(III) reduction. The results support a hypothesis of Fe(III)-mediated CH(4) oxidation in the contaminated aquifer.
在明尼苏达州贝米吉附近的一个产甲烷原油污染的含水层中,随着地下水流路径中溶解 CH(4) 浓度的降低,以及 δ(13) C(CH) (4) 的正值偏移和 δ(13) C(DIC) 的负值偏移,表明存在微生物介导的 CH(4)氧化。通过对穿过地下水面的电子受体迁移的计算,包括扩散、补给、气泡的捕获和释放,表明这些过程最多只能解释观察到的总还原碳氧化的 15%,包括 CH(4)。在厌氧羽流中,特征 Fe(III)还原属 Geobacter 是测试的微生物组中最丰富的,并且随着时间的推移可观察到可利用沉积物铁的耗尽,证实了与铁还原偶联的还原碳氧化是一个重要过程。电子质量平衡计算表明,含水层中的有机碳源,BTEX 和非挥发性溶解有机碳,不足以解释沉积物 Fe(III)的损失,这意味着 CH(4)氧化也可能与 Fe(III)还原有关。结果支持了在受污染含水层中 Fe(III)介导的 CH(4)氧化的假说。
