Multiphysics analysis of fuel fragmentation, relocation, and dispersal susceptibility–Part 1: Overview and code coupling strategies-Reference-Cited by-同舟云学术

Multiphysics analysis of fuel fragmentation, relocation, and dispersal susceptibility–Part 1: Overview and code coupling strategies

Published:2023-10 Issue: Volume:191 Page:109913
ISSN:0306-4549
Container-title:Annals of Nuclear Energy
language:en
Short-container-title:Annals of Nuclear Energy

Author:

Greenquist Ian,Wysocki Aaron,Hirschhorn Jake,Capps Nathan

Publisher

Elsevier BV

Subject

Nuclear Energy and Engineering

Reference19 articles.

1. Bajorek, S., Gavrilas, M., Gingrich, C., Han, J., Hogan, K., Kelly, J., Krotiuk, W., Lauben, N., Lu, S., Murray, C., Odar, F., Rhee, G., Rubin, M., Smith, S., Staudenmeier, J., Uhle, J., Wang, W., Welter, K., Han, J., Klein, V., Burton, W., Danna, J.a., Jolicoeur, J., Basu, S., Madni, I., Marshall, S., Velazquez, A., Kadambi, P., Bessette, D., Bennet, M., Salay, M., Ireland, A., Macon, W., Eltawila, F., Guan, Y., Ebert, D., Du, D., Fang, T., He, W., Straka, M., Palmrose, D., Jones, Mahaffy, J., Trujillo, M., Jelinek, M., Lazor, M., Hansell, B., Watson, J., Meholic, M., Aktas, B., Amoruso, C., Barber, D., Bolander, M., Caraher, D., Delfino, C., Fletcher, D., Larson, D., Lucas, Mortensen, G., Palazov, V., Prelewicz, D., Shumway, R., Tompot, R., Wang, D., Spore, J., Boyack, B., Dearing, S., Durkee, J., Elson, J., Giguere, P., Johns, R., Lime, J., Lin, J.-C., Pimentel, D., Downar, T., Miller, M., Gan, J., Joo, H., Xu, Y., Kozlowski, T., Jung Lee, D., Herrero, R., Jeong, J.H., Huh, C.W., Shin, A.D., TRACE V5.0 Theory Manual: Field Equations, Solution Methods, and Physical Models, (n.d.). https://www.nrc.gov/docs/ML1200/ML120060218.pdf (accessed November 23, 2022).

2. Interpretation of Research on Fuel Fragmentation, Relocation, and Dispersal at HIgh Burnup;Bales,2021

3. Capps, N., Greenquist, I., Wysocki, A., Hirschhorn, J., Multiphysics Analysis of Fuel Fragmentation, Relocation, and Dispersal Susceptibility-Part 2: High Burnup Steady State Operating and Fuel Performance Conditions, Annals of Nuclear Energy. (Unpublished manuscript).

4. Development and demonstration of a methodology to evaluate high burnup fuel susceptibility to pulverization under a loss of coolant transient;Capps;Nucl. Eng. Des.,2020

5. Model for determining rupture area in Zircaloy cladding under LOCA conditions;Capps;Nucl. Eng. Des.,2023

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