Updated
Updated · SciTechDaily · Jul 12
Bacteria Lock 95% of Dissolved Uranium Into Stable FeU(V)O4 in Mine Water
Updated
Updated · SciTechDaily · Jul 12

Bacteria Lock 95% of Dissolved Uranium Into Stable FeU(V)O4 in Mine Water

3 articles · Updated · SciTechDaily · Jul 12

Summary

  • After 130 days, microbes in flooded uranium-mine water left only about 5% of dissolved uranium in solution, converting much of it into solid FeU(V)O4, researchers reported.
  • Glycerol-fed bacteria under oxygen-free conditions accumulated uranium in their cell walls, then helped drive it into the rare pentavalent uranium(V) state bound with iron and oxygen.
  • Microscopy and spectroscopy at HZDR, ESRF’s Rossendorf Beamline and the University of Granada identified the unexpectedly high share of uranium(V), which is usually rare and short-lived in the environment.
  • The compound had previously been observed in Croatian contaminated soil and remained stable for more than 25 years, but the new study points to bacteria as a natural formation pathway.
  • Researchers say the finding could aid bioremediation of contaminated groundwater and mine water, though they still need to test how reliably the process works outside the lab.

Insights

A new discovery shows bacteria can trap uranium. Is this a permanent fix or a future environmental risk?
Can these uranium-eating bacteria be deployed to finally clean up the world's most toxic mining sites?

Bacterial Bioremediation Achieves 96% Uranium Reduction via Stable FeU(V)O₄ Formation: A New Era for Contaminated Site Cleanup

Overview

In May 2026, a groundbreaking study published in Nature Communications reported a major advance in uranium bioremediation. Researchers discovered that bacteria can immobilize uranium by forming a stable pentavalent uranium compound, FeU(V)O₄, offering a promising new solution for cleaning up uranium-contaminated sites. The team conducted experiments using water from a former uranium mine in Germany, introducing glycerol as a carbon source and maintaining oxygen-free conditions. This novel mechanism highlights the remarkable ability of bacteria to transform and stabilize uranium, paving the way for more effective and sustainable approaches to address uranium pollution.

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