LESSONS
LEARNED
Disclaimer: The Lessons Learned Database includes the incidents that were voluntarily submitted. The database is not a comprehensive source for all incidents that have occurred.

Three-dimensional all-speed CFD code for safety analysis of nuclear reactor containment: Status of GASFLOW parallelization, model development, validation and application

Xiao, J. J., Travis, J. R., Royl, P. ., Necker, G. ., Svishchev, A. ., & Jordan, T. . (2016). Three-dimensional all-speed CFD code for safety analysis of nuclear reactor containment: Status of GASFLOW parallelization, model development, validation and application. Nuclear Engineering and Design, 301, 290-310+. https://doi.org/10.1016/j.nucengdes.2015.12.033 (Original work published 2025)
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The role of CFD combustion modelling in hydrogen safety management - VI: Validation for slow deflagration in homogeneous hydrogen-air-steam experiments

Rakhimov, A. C., Visser, D. C., Holler, T. ., & Komen, E. M. J. (2017). The role of CFD combustion modelling in hydrogen safety management - VI: Validation for slow deflagration in homogeneous hydrogen-air-steam experiments. Nuclear Engineering and Design, 311, 142-155+. https://doi.org/10.1016/j.nucengdes.2016.11.034 (Original work published 2025)
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The role of CFD combustion modeling in hydrogen safety management - III: Validation based on homogeneous hydrogen-air-diluent experiments

Sathiah, P. ., Komen, E. ., & Roekaerts, D. . (2015). The role of CFD combustion modeling in hydrogen safety management - III: Validation based on homogeneous hydrogen-air-diluent experiments. Nuclear Engineering and Design, 289, 296-310+. https://doi.org/10.1016/j.nucengdes.2014.05.042 (Original work published)
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The role of CFD combustion modeling in hydrogen safety management - IV: Validation based on non-homogeneous hydrogen-air experiments

Sathiah, P. ., Komen, E. ., & Roekaerts, D. . (2016). The role of CFD combustion modeling in hydrogen safety management - IV: Validation based on non-homogeneous hydrogen-air experiments. Nuclear Engineering and Design, 310, 507-519+. https://doi.org/10.1016/j.nucengdes.2015.05.030 (Original work published)
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The role of CFD combustion modeling in hydrogen safety management - V: Validation for slow deflagrations in homogeneous hydrogen-air experiments

Sathiah, P. ., Holler, T. ., Kljenak, I. ., & Komen, E. . (2016). The role of CFD combustion modeling in hydrogen safety management - V: Validation for slow deflagrations in homogeneous hydrogen-air experiments. Nuclear Engineering and Design, 310, 520-531+. https://doi.org/10.1016/j.nucengdes.2016.06.030 (Original work published)
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The role of CFD combustion modeling in hydrogen safety management - VII: Validation for hydrogen deflagration in large-scale hydrogen-air-steam experiment

Holler, T. ., Komen, E. M. J., & Kljenak, I. . (2019). The role of CFD combustion modeling in hydrogen safety management - VII: Validation for hydrogen deflagration in large-scale hydrogen-air-steam experiment. Nuclear Engineering and Design, 342, 133-146+. https://doi.org/10.1016/j.nucengdes.2018.11.033 (Original work published 2025)
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Prediction of Deflagrative Explosions in Variety of Closed Vessels

Rudy, W. ., Pekalski, A. ., Makarov, D. ., Teodorczyk, A. ., & Molkov, V. . (2021). Prediction of Deflagrative Explosions in Variety of Closed Vessels. Energies, 14(8), 19+. https://doi.org/10.3390/en14082138 (Original work published 2025)
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Physical model of onboard hydrogen storage tank thermal behaviour during fuelling

Molkov, V. ., Dadashzadeh, M. ., & Makarov, D. . (2019). Physical model of onboard hydrogen storage tank thermal behaviour during fuelling. International Journal of Hydrogen Energy, 44(8), 4374-4384+. https://doi.org/10.1016/j.ijhydene.2018.12.115 (Original work published)
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Numerical validation of pressure peaking from an ignited hydrogen release in a laboratory-scale enclosure and application to a garage scenario

Hussein, H. G., Brennan, S. ., Shentsov, V. ., Makarov, D. ., & Molkov, V. . (2018). Numerical validation of pressure peaking from an ignited hydrogen release in a laboratory-scale enclosure and application to a garage scenario. International Journal of Hydrogen Energy, 43(37), 17954-17968+. https://doi.org/10.1016/j.ijhydene.2018.07.154 (Original work published)
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Numerical modelling of isothermal release and distribution of helium and hydrogen gases inside the AIHMS cylindrical enclosure

Prabhakar, A. ., Agrawal, N. ., Raghavan, V. ., & Das, S. K. (2017). Numerical modelling of isothermal release and distribution of helium and hydrogen gases inside the AIHMS cylindrical enclosure. International Journal of Hydrogen Energy, 42(22), 15435-15447+. https://doi.org/10.1016/j.ijhydene.2017.04.296 (Original work published)
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This material was prepared as an account of work sponsored by an agency of the United States Government.
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