In light water reactor fuel, gaseous fission products segregate to grain boundaries, resulting in the nucleation and growth of large intergranular fission gas bubbles. The segregation rate is controlled by diffusion of fission gas atoms through the grains and interaction with the boundaries. Based on the mechanisms established from earlier density functional theory (DFT) and empirical potential calculations, diffusion models for xenon (Xe), uranium (U) vacancies and U interstitials in UO₂ have been derived for both intrinsic (no irradiation) and irradiation conditions. Segregation of Xe to grain boundaries is described by combining the bulk diffusion model with a model for the interaction between Xe atoms and three different grain boundaries in UO₂ (Σ5 tilt, Σ5 twist and a high angle random boundary), as derived from atomistic calculations. The present model does not attempt to capture nucleation or growth of fission gas bubbles at the grain boundaries. The point defect and Xe diffusion and segregation models are implemented in the MARMOT phase field code, which is used to calculate effective Xe and U diffusivities as well as to simulate Xe redistribution for a few simple microstructures.
Andersson, David A., et al. "Multiscale simulation of xenon diffusion and grain boundary segregation in UO₂." Journal of Nuclear Materials, vol. 462, no. C, Jul. 2015. https://doi.org/10.1016/j.jnucmat.2015.03.019
Andersson, David A., Tonks, Michael R., Casillas, Luis, Vyas, Shyam, Nerikar, Pankaj, Uberuaga, Blas P., & Stanek, Christopher R. (2015). Multiscale simulation of xenon diffusion and grain boundary segregation in UO₂. Journal of Nuclear Materials, 462(C). https://doi.org/10.1016/j.jnucmat.2015.03.019
Andersson, David A., Tonks, Michael R., Casillas, Luis, et al., "Multiscale simulation of xenon diffusion and grain boundary segregation in UO₂," Journal of Nuclear Materials 462, no. C (2015), https://doi.org/10.1016/j.jnucmat.2015.03.019
@article{osti_1193643,
author = {Andersson, David A. and Tonks, Michael R. and Casillas, Luis and Vyas, Shyam and Nerikar, Pankaj and Uberuaga, Blas P. and Stanek, Christopher R.},
title = {Multiscale simulation of xenon diffusion and grain boundary segregation in UO₂},
annote = {In light water reactor fuel, gaseous fission products segregate to grain boundaries, resulting in the nucleation and growth of large intergranular fission gas bubbles. The segregation rate is controlled by diffusion of fission gas atoms through the grains and interaction with the boundaries. Based on the mechanisms established from earlier density functional theory (DFT) and empirical potential calculations, diffusion models for xenon (Xe), uranium (U) vacancies and U interstitials in UO₂ have been derived for both intrinsic (no irradiation) and irradiation conditions. Segregation of Xe to grain boundaries is described by combining the bulk diffusion model with a model for the interaction between Xe atoms and three different grain boundaries in UO₂ (Σ5 tilt, Σ5 twist and a high angle random boundary), as derived from atomistic calculations. The present model does not attempt to capture nucleation or growth of fission gas bubbles at the grain boundaries. The point defect and Xe diffusion and segregation models are implemented in the MARMOT phase field code, which is used to calculate effective Xe and U diffusivities as well as to simulate Xe redistribution for a few simple microstructures.},
doi = {10.1016/j.jnucmat.2015.03.019},
url = {https://www.osti.gov/biblio/1193643},
journal = {Journal of Nuclear Materials},
issn = {ISSN 0022-3115},
number = {C},
volume = {462},
place = {United States},
publisher = {Elsevier},
year = {2015},
month = {07}}