With implications that could eventually benefit sites forever changed by nuclear contamination, researchers at Michigan State University have unravelled the mystery of how microbes generate electricity while cleaning up nuclear waste and other toxic metals.
Details of the process, which can be improved and patented, are published in the current issue of the Proceedings of the National Academy of Sciences.
“Geobacter bacteria are tiny micro-organisms that can play a major role in cleaning up polluted sites around the world,” said Gemma Reguera, who is an MSU AgBioResearch scientist. “Uranium contamination can be produced at any step in the production of nuclear fuel, and this process safely prevents its mobility and the hazard for exposure.”
The ability of Geobacter to immobilize uranium has been well documented. However, identifying the Geobacters' conductive pili or nanowires as doing the yeoman's share of the work is a new revelation, according to a Michigan State University press release.
Nanowires, hair-like appendages found on the outside of Geobacters, are the managers of electrical activity during a cleanup.
“Our findings clearly identify nanowires as being the primary catalyst for uranium reduction,” Reguera said. “They are essentially performing nature's version of electroplating with uranium, effectively immobilizing the radioactive material and preventing it from leaching into groundwater.”