b'References:[1.] F. Nagase, "2.23 - Behavior of LWR Fuel During Loss-of-Coolant Accidents", in: R.J.M.B.T.-C.N.M. Konings (Ed.), Elsevier, Oxford, 2012 pp. 595608. https://doi.org/10.1016/B978-0-08-056033-5.00045-8.[2.] M. Flanagan, A. Oberlander, B.C., Puranen, "Fuel fragmentation and dispersal under LOCA conditions: experimental observations", in: TopFuel 2013, 2013.[3.] A. Bianco, C. Vitanza, M. Seidl, A. Wensauer, W. Faber, R. Macin-Juan, "Experimental investigation on the causes for pellet fragmen-tation under LOCA conditions", J. Nucl. Mater. 465 (2015) p. 260267. https://doi.org/10.1016/j.jnucmat.2015.05.035.[4.] K. Kulacsy, "Mechanistic modelhigh-burnup fuel", Nucl. Eng. Des.Figure 4. Radial profile of the 367 (2020) p. 110811. https:// measured thermal diffusivity of for the fragmentation of the high- doi.org/10.1016/j.nuceng- the high burnup UO 2sampleburnup structure during LOCA", J.des.2020.110811.Nucl. Mater. 466 (2015) p. 409416. https://doi.org/10.1016/j. [7.] L.O. Jernkvist, "Modelling of jnucmat.2015.08.015. fine fragmentation and fission [5.] J.A. Turnbull, S.K. Yagnik, M. Hirai,gas release of UO 2fuel in acci-D.M. Staicu, C.T. Walker, "An As- dent conditions", EPJ Nucl. Sci. sessment of the Fuel PulverizationTechnol. 5 (2019). https://doi.Threshold During LOCA-Typeorg/10.1051/epjn/2019030.Temperature Transients", Nucl.[8.] L.O. Jernkvist, "A review of analyt-Sci. Eng. 179 (2015) p. 477485.ical criteria for fission gas induced 10.13182/NSE14-20. fragmentation of oxide fuel in [6.] N. Capps, Y. Yan, A. Raftery, Z.accident conditions", Prog. Nucl. Burns, T. Smith, K. Terrani, K.Energy. 119 (2020) p. 103188. Yueh, M. Bales, K. Linton, "Inte- https://doi.org/10.1016/j.pnu-gral LOCA fragmentation test oncene.2019.103188.2021|AFC ACCOMPLISHMENTS 57'