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Uranium science researchers investigate feasibility of intentional nuclear forensics

Intentional nuclear forensics: A high-stakes game of tag

Redish orange sample of material, round in size and small (taking up only a quarter of the image). There is a dark grey floor and blue light background
A sample of finchite, a uranium mineral discovered by Oak Ridge National Laboratory scientist Tyler Spano and collaborators at the United States Geological Survey, is examined with a light scattering technique known as Fourier-infrared spectroscopy. Credit: Jeff Otto/ORNL, U.S. Dept. of Energy

Despite strong regulations and robust international safeguards, authorities routinely interdict nuclear materials outside of regulatory control. Researchers at the Department of Energy’s Oak Ridge National Laboratory are exploring a new method that would give authorities the ability to analyze intercepted nuclear material and determine where it originated. Their findings were published recently in the Journal of Nuclear Materials. 

The work is part of a multi-laboratory research venture, funded by the National Nuclear Security Administration, investigating whether it is possible to intentionally add forensic signatures – called “taggants” or “dopants” – to nuclear fuels. Similar to how sulfur added to natural gas aids in quick identification of gas leaks, tagged nuclear materials found outside of regulatory control could be rapidly analyzed to support provenance determination.

Woman with her hair down is in a lab wearing a white coat and protective safety glasses.
ORNL Nuclear Security Scientist Tyler Spano works with uranium samples in her laboratory. Credit: Carlos Jones/ORNL, U.S. Dept. of Energy

“The technical nuclear forensics community is dedicated to understanding where materials outside of regulatory control originated and how long they have been outside of regulatory control,” said Ashley Shields, a computational chemist in ORNL’s Nuclear Nonproliferation Division. “This information is key for law enforcement investigations.”

While the broader research venture is concerned with whether taggants can be added in a way that fuel fabricators can produce, without compromising safety or performance, the ORNL team is looking at the materials that occur early in the nuclear fuel cycle to determine when – if at all – a taggant could be added to provide a novel, measurable signature throughout the fuel cycle. 

“As part of our research, we synthesize tagged materials and analyze whether the taggant changed the original material’s properties in a way that we can clearly attribute to the presence of the tag,” said Tyler Spano, a nuclear security scientist at ORNL and the publication’s lead author. 

By studying the physiochemical behavior of the taggants and how they persist – or don’t – during relevant chemical processing, the team hopes to identify effective forensic taggant materials. The research, which was highlighted by the Nuclear Forensics International Technical Working Group as a notable publication, represents a step toward understanding the feasibility of intentional nuclear forensics and, ultimately, the ability to determine the provenance of nuclear materials found outside of regulatory control.

UT-Battelle manages ORNL for the Department of Energy’s Office of Science, the single largest supporter of basic research in the physical sciences in the United States. The Office of Science is working to address some of the most pressing challenges of our time. For more information visit https://energy.gov/science.