"Development of planar PyC/SiC diffusion couples to investigate irradiation effects and microstructural variation on fission product diffusion" Tyler Gerczak, John Hunn, Brian Jolly, Austin Schumacher, Anne Campbell, John Dyer, Xunxiang Hu, Proceedings of HTR 2018 Vol. 2018 0047 | ||
"Diffusion of fissile inventory in AGR-1 Triso fuel particles as a function of temperature & silver retention" Rachel Seibert, Jeff Terry, Tyler Gerczak, Kurt Terrani, John Hunn, Fred Montgomery, Charles Baldwin, Transactions of the American Nuclear Society Vol. 118 2018 1486-1487 Link | ||
"Electron Microscopy Study of Pd, Ag, and Cs in Carbon Areas in the Locally Corroded SiC Layer in a Neutron-Irradiated TRISO Fuel Particle" Haiming Wen, Isabella van Rooyen, John Hunn, Tyler Gerczak, Journal of the European Ceramic Society Vol. 38 (2018) 2016 4173-4188 Link | ||
"Local atomic structure of Pd and Ag in the SiC containment layer of TRISO fuel particles fissioned to 20% burn-up"
John Hunn, Rachel Seibert, Kurt Terrani, Jeff Terry, Daniel Velazquez, Charles Baldwin, Fred Montgomery,
Journal of Nuclear Materials
Vol. 500
2017
316-326
Link
The structure and speciation of fission products within the SiC barrier layer of tristructural-isotropic (TRISO) fuel particles irradiated to 19.6% fissions per initial metal atom (FIMA) burnup in the Advanced Test Reactor (ATR) at Idaho National Laboratory (INL) was investigated. As-irradiated fuel particles, as well as those subjected to simulated accident scenarios, were examined. The TRISO particles were characterized using synchrotron X-ray absorption fine-structure spectroscopy (XAFS) at the Materials Research Collaborative Access Team (MRCAT) beamline at the Advanced Photon Source. The TRISO particles were produced at Oak Ridge National Laboratory under the Advanced Gas Reactor Fuel Development and Qualification Program and sent to the ATR for irradiation. XAFS measurements on the palladium and silver K-edges were collected using the MRCAT undulator beamline. Analysis of the Pd edge indicated the formation of palladium silicides of the form PdxSi (2?=?x?=?3). In contrast, Ag was found to be metallic within the SiC shell safety tested to 1700?°C. To the best of our knowledge, this is the first result demonstrating metallic bonding of silver from fissioned samples. Knowledge of these reaction pathways will allow for better simulations of radionuclide transport in the various coating layers of TRISO fuels for next generation nuclear reactors. They may also suggest different ways to modify TRISO particles to improve their fuel performance and to mitigate potential fission product release under both normal operation and accident conditions. |
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"Mechanical characteristics of SiC coating layer in TRISO fuel particles"
Thak Sang Byun, David Frazer, Peter Hosemann, John Hunn, Maria Okuniewski, Kurt Terrani, Gokul Vasudevamurthy, J. N. Matros, Brian Jolly,
Journal of Nuclear Materials
Vol. 442
2013
133-142
Link
Tristructural isotropic (TRISO) particles are considered as advanced fuel forms for a variety of fission platforms. While these fuel structures have been tested and deployed in reactors, the mechanical properties of these structures as a function of production parameters need to be investigated in order to ensure their reliability during service. Nanoindentation techniques, indentation crack testing, and half sphere crush testing were utilized in order to evaluate the integrity of the SiC coating layer that is meant to prevent fission product release in the coated particle fuel form. The results are complimented by scanning electron microscopy (SEM) of the grain structure that is subject to change as a function of processing parameters and can alter the mechanical properties such as hardness, elastic modulus, fracture toughness and fracture strength. Through utilization of these advanced techniques, subtle differences in mechanical properties that can be important for in-pile fuel performance can be distinguished and optimized in iteration with processing science of coated fuel particle production. |
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"Structural Characterization of Fission Products in Irradiated TRISO Fuels using Transmission Kikuchi Diffraction, Transmission Electron Microscopy, and Synchrotron X-ray Absorption Spectroscopy" John Hunn, Chad Parish, Jeff Terry, Rachel Seibert, Charles Baldwin, Kurt Terrani, Microscopy & Microanalysis Vol. 23 2017 1118-1119 Link |
" Fission Product and Actinide Distribution in the Sic Layer of Fissioned Triso Fuel Particles" Tyler Gerczak, John Hunn, Keith Leonard, Jeff Terry, 2017 ANS Annual Meeting [unknown] | |
"Development of Planar PyC/SiC Diffusion Couples to Investigate Irradiation Effects and Microstructural Variation on Fission Product Diffusion" Tyler Gerczak, Rachel Seibert, John Hunn, Brian Jolly, Austin Schumacher, Xunxiang Hu, Anne Campbell, GCR Program Review Meeting June 18-19, (2019) | |
"Diffusion of fissile inventory in AGR-1 Triso fuel particles as a function of temperature & silver retention" Rachel Seibert, Jeff Terry, Tyler Gerczak, Kurt Terrani, John Hunn, Fred Montgomery, Charles Baldwin, The American Nuclear Society Annual Meeting June 17-21, (2018) | |
"Fabrication of PyC/SiC diffusion couples using fluidized bed CVD techniques for radiation enhanced diffusion testing" Brian Jolly, Tyler Gerczak, John Hunn, Austin Schumacher, Anne Campbell, The Materials Society Annual Conference March 11-15, (2018) |
CINR Awards Announced - Eight projects were selected Projects will take advantage of NSUF capabilities to investigate important nuclear fuel and material applications. Thursday, June 27, 2019 - Calls and Awards |
The Nuclear Science User Facilities (NSUF) is the U.S. Department of Energy Office of Nuclear Energy's only designated nuclear energy user facility. Through peer-reviewed proposal processes, the NSUF provides researchers access to neutron, ion, and gamma irradiations, post-irradiation examination and beamline capabilities at Idaho National Laboratory and a diverse mix of university, national laboratory and industry partner institutions.
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