Modeling Deep Burn TRISO particle nuclear fuel

T. M. Besmann, R. E. Stoller, G. Samolyuk, P. C. Schuck, S. I. Golubov, S. P. Rudin, J. M. Wills, J. D. Coe, B. D. Wirth, S. Kim, D. D. Morgan, I. Szlufarska

Research output: Contribution to journalArticlepeer-review

13 Scopus citations

Abstract

Under the DOE Deep Burn program TRISO fuel is being investigated as a fuel form for consuming plutonium and minor actinides, and for greater efficiency in uranium utilization. The result will thus be to drive TRISO particulate fuel to very high burn-ups. In the current effort the various phenomena in the TRISO particle are being modeled using a variety of techniques. The chemical behavior is being treated utilizing thermochemical analysis to identify phase formation/transformation and chemical activities in the particle, including kernel migration. Density functional theory is being used to understand fission product diffusion within the plutonia oxide kernel, the fission product's attack on the SiC coating layer, as well as fission product diffusion through an alternative coating layer, ZrC. Finally, a multiscale approach is being used to understand thermal transport, including the effect of radiation damage induced defects, in a model SiC material.

Original languageEnglish
Pages (from-to)181-189
Number of pages9
JournalJournal of Nuclear Materials
Volume430
Issue number1-3
DOIs
StatePublished - Nov 2012

Funding

This work was funded under the U.S. Department of Energy – NE Deep Burn program. The authors wish to thank T.R. Allen, S.L. Voit, and Y. Katoh for helpful discussions. K.T. Clarno performed the SCALE calculations.

FundersFunder number
U.S. Department of Energy

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