Study site showing locations of magnetite packs and core samples (modified from USGS, 2020). Transect A–A' is shown in Figure 2. Mineral columns are shown as red circles. Core samples are shown as black circles for core samples retrieved in 2016 (1604), 2017 (1713, 1709, 1714), and 2019 (1902, 1903, 1905). Credit: Journal of Geophysical Research: Biogeosciences (2022). DOI: 10.1029/2021JG006560

In August 1979, an oil pipeline burst near Bemidji, Minn., spraying 1.7 million liters of crude oil onto the ground. Following cleanup, 400,000 liters that had seeped into sediments still remained. Recognizing a unique opportunity, research groups began to study the site to gain new insights into the long-term dynamics of oil spills.

Since then, some studies have observed changes in the of contaminated sediments at what is now known as the National Crude Oil Spill Fate and Natural Attenuation Research Site, managed by the U.S. Geological Survey. Such magnetic changes can reflect—and therefore help monitor—the degradation of spilled oil.

In 2014, scientists first reported a strong magnetic response within the oil layer. However, by the end of 2015, the magnetization had almost totally disappeared. Now, Ohenhen et al report new observations that illuminate the processes likely responsible for the changes in magnetism at the Bemidji site. Specifically, a magnetic, iron-containing mineral known as magnetite in the appears to be both dissolving and undergoing into the less magnetic mineral maghemite, and microbes may be driving much of this conversion.

Between 2016 and 2019, were sampled from various parts of the spill site, and the researchers measured their magnetic and mineral properties at the Institute for Rock Magnetism. The scientists also installed packets of magnetite below the in the spill site and sampled them periodically to capture any changes.

In line with earlier data, the experiments showed that magnetization in the sediments decreased over time. However, the data point to a few potential processes underlying the decreased magnetization, which may vary depending on the precise location in the site.

In sediments outside of the remaining underground oil plume, the data suggest that a minor decrease in magnetization occurred via conversion of magnetite to maghemite through a nonbiological chemical process that relies on oxygen. Within the plume, the researchers found evidence, including signs of decreased sediment grain size, for a combination of dissolving magnetite and conversion to maghemite.

Notably, conversion to maghemite within the plume occurs in a zone known to contain very little oxygen. Yet nonbiological conversion is typically driven by oxygen. Thus, the researchers hypothesize, within-plume conversion may occur as a result of life-sustaining biological processes of anaerobic microbes in this zone.

These findings, published in the Journal of Geophysical Research: Biogeosciences, add to a body of evidence suggesting that microbes can alter the magnetism of Earth materials. Future research could help identify specific microbes that may convert magnetite to maghemite at the Bemidji site.

More information: Leonard O. Ohenhen et al, Microbially Induced Anaerobic Oxidation of Magnetite to Maghemite in a Hydrocarbon‐Contaminated Aquifer, Journal of Geophysical Research: Biogeosciences (2022). DOI: 10.1029/2021JG006560

Provided by Eos