Detection and analysis of particles with failed SiC in AGR-1 fuel compacts

John D. Hunn, Charles A. Baldwin, Tyler J. Gerczak, Fred C. Montgomery, Robert N. Morris, Chinthaka M. Silva, Paul A. Demkowicz, Jason M. Harp, Scott A. Ploger

Research output: Contribution to journalArticlepeer-review

55 Scopus citations

Abstract

As the primary barrier to release of radioactive isotopes emitted from the fuel kernel, retention performance of the SiC layer in tristructural isotropic (TRISO) coated particles is critical to the overall safety of reactors that utilize this fuel design. Most isotopes are well-retained by intact SiC coatings, so pathways through this layer due to cracking, structural defects, or chemical attack can significantly contribute to radioisotope release. In the US TRISO fuel development effort, release of 134Cs and 137Cs are used to detect SiC failure during fuel compact irradiation and safety testing because the amount of cesium released by a compact containing one particle with failed SiC is typically ten or more times higher than that released by compacts without failed SiC. Compacts with particles that released cesium during irradiation testing or post-irradiation safety testing at 1600–1800 °C were identified, and individual particles with abnormally low cesium retention were sorted out with the Oak Ridge National Laboratory (ORNL) Irradiated Microsphere Gamma Analyzer (IMGA). X-ray tomography was used for three-dimensional imaging of the internal coating structure to locate low-density pathways through the SiC layer and guide subsequent materialography by optical and scanning electron microscopy. All three cesium-releasing particles recovered from as-irradiated compacts showed a region where the inner pyrocarbon (IPyC) had cracked due to radiation-induced dimensional changes in the shrinking buffer and the exposed SiC had experienced concentrated attack by palladium; SiC failures observed in particles subjected to safety testing were related to either fabrication defects or showed extensive Pd corrosion through the SiC where it had been exposed by similar IPyC cracking.

Original languageEnglish
Pages (from-to)36-46
Number of pages11
JournalNuclear Engineering and Design
Volume306
DOIs
StatePublished - Sep 1 2016

Funding

This work was supported by the U.S. Department of Energy , Office of Nuclear Energy , under the Very High Temperature Reactor Technology Development Office Advanced Gas Reactor Fuel Development and Qualification Program. Assistance with quantitative analysis of actinide and fission product inventories was provided by the ORNL Nuclear Analytical Chemistry & Isotopics Laboratory and the INL Analytical Laboratory, and many hot cell activities were performed by staff of the ORNL Irradiated Fuels Examination Laboratory and the INL Hot Fuel Examination Facility.

FundersFunder number
Very High Temperature Reactor Technology Development Office Advanced Gas Reactor Fuel Development and Qualification Program
U.S. Department of Energy
Office of Nuclear Energy

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