References
- Humphries LL, Beeny BA, Gelbard F, et al. MELCOR computer code manuals vol. 2: reference manual version 2.2.9541. Albuquerque (NM):Sandia National Laboratories;2017. (SAND2017-0876 O).
- Kajimoto M, Kuramatsu K, Watanabe N, et al. Development of THALES-2, A computer code for coupled thermal–hydraulics and radionuclides transport analyses for severe accident at LWRs and its application to analysis of radionuclides revaporization phenomena. Proceedings of international topical meeting on safety of thermal reactors, 1991; 21–25 July 1991; Portland, Oregon.
- Pellegrini M, Dolganov K, Herranz LE, et al. Benchmark study of the accident at the Fukushima Daiichi NPS: best-estimate case comparison. Nuclear Technology. 2016;196(2):198–210.
- Pellegrini M, Herranz L, Sonnenkalb M, et al. Main findings, remaining uncertainties and lessons learned from the OECD/NEA BSAF project. Nuclear Technology. 2020;206(9):1449–1463.
- Clément B, Simondi-Teisseire B. STEM: an IRSN project on source term evaluation and mitigation. Transactions. 2010;103(1):475–476.
- Funke F, Langrock G, Kanzleiter T, et al. Iodine oxides in large-scale Thai tests. Nuclear Engineering and Design. 2012 April;245:206–222.
- Moriyama K, Maruyama Y, Nakamura H (2011). Kiche: a simulation tool for kinetics of iodine chemistry in the containment of light water reactors under severe accident conditions. Ibaraki-ken (Japan): Japan Atomic Energy Agency; 2011, (JAEA-Data/Code 2010-034).
- Furuta S, Sumiya S, Watanabe H, et al. [Results of the environmental radiation monitoring following the accident at the Fukushima Daiichi nuclear power plant—Interim report (Ambient radiation dose rate, radioactivity concentration in the air and radioactivity concentration in the fallout)]. Ibaraki-ken (Japan): Japan Atomic Energy Agency; 2011, (JAEA-Reviw 2011-035) [in Japanese].
- Ohkura T, Oishi T, Taki M, et al. Emergency monitoring of environmental radiation and atmospheric radionuclides at Nuclear Science Research Institute, JAEA following the accident of Fukushima Daiichi nuclear power plant. Ibaraki-ken (Japan): Japan Atomic Energy Agency; 2012, (JAEA-DATA/Code 2012-010).
- Ishikawa J. Analysis for accident progression with THALES2 code. Proceedings of the technical workshop on TEPCO’s Fukushima Dai-ichi NPS accident; 23–24 July 2012; Tokyo, Japan.
- Hoshi H, Ogino M, Kawabe R, et al. Computational analysis on accident progression of Fukushima Dai-ichi NPS. Proceedings of PSAM 2013; 14–18 April 2013; Tokyo, Japan.
- Mizokami S. Detailed analysis of the accident progression of units 1 to 3 by using MAAP Code. Proceedings of technical workshop on the accident of TEPCO’s Fukushima Dai-ichi NPS accident; 23-24 July 2012; Tokyo, Japan.
- Haynes W. CRC handbook of chemistry and physics. Boca Raton (FL): CRC Press; 2017. p. 2–12.
- Whitman WG. The two-film theory of gas absorption. Chemical and Metallurgical Engineering. 1923;29:146–148.
- Wren JC, Glowa GA, Ball JM. A simplified model for containment iodine chemistry and transport: model description and validation using stainless steel RTF test results. OECD workshop on iodine aspects of severe accident management; 18–20 May 1999 Vantaa, Finland.
- Cantrel L, March P. Mass transfer modeling with and without evaporation for iodine chemistry in the case of a severe accident. Nuclear Technology. 2006;154(2):170–185.
- Cantrel L. Radiochemistry of iodine: outcomes of the CAIMAN program. Nuclear Technology. 2006;156(1):11–28.
- Burley G. Evaluation of fission product release and transport for a fuel handling accident. Rockville (MD):Nuclear Regulatory Commission;1971. (ADAMS Accession No. ML8402080322).
- Johnson AI, Besik F, Hamielec AE. Mass transfer from a single rising bubble. The Canadian Journal of Chemical Engineering. 1969;47(6):559–564.
- Parsly LF. Design considerations of reactor containment spray systems: part IV calculation of iodine water partition coefficients. Oak Ridge (TN): Oak Ridge National Laboratory; 1971, (ORNL-TM-2412).
- Glowa GA, Wren JC. Aqueous-gas phase partitioning and hydrolysis of organic iodides. Canadian Journal of Chemistry. 2003;81(3):230–243.
- Moriyama K, Tashiro S, Chiba N, et al. Experiment on the gaseous iodine release from irradiated cesium iodide solutions. Ibaraki-ken (Japan): Japan Atomic Energy Agency; 2011, (JAEA-Research 2011-016).
- Ball J, Glowa G, Wren JC, et al. ISP 41 containment iodine computer code exercise based on a radioiodine test facility (RTF) experiment. Issy-les-Moulineaux (France): Organisation for Economic Co-operation and Development; 2000, (NEA/CSNI/R(2000)6/VOL1-2).
- Ball J, Marchand C, Allelein H, et al. ISP-41-follow-up exercise: phase2 iodine code comparison exercise against CAIMAN and RTF experiments. Issy-les-Moulineaux (France): Organisation for Economic Co-operation and Development; 2004, (NEA/CSNI/R(2004)16).
- Ishikawa J, Kawaguchi K, Maruyama Y. Analysis for iodine release from unit 3 of Fukushima Dai-ichi nuclear power plant with consideration of water phase iodine chemistry. Journal of Nuclear Science and Technology. 2015;52(3):308–314.
- Gupta S, Herranz LE, Van Dorsselaere JP. Integration of pool scrubbing research to enhance source-term calculations (IPRESCA). 8th european review meeting on severe accident research; 2017 Warsaw, Poland.
- Fischer K, Weber G, Funke F, et al. Experimental determination and analysis of iodine mass transfer coefficients from Thai test Iod-23. 5th european review meeting on severe accident research; 2012 Cologne, Germany.
- Higbie R. The rate of absorption of a pure gas into a still liquid during short periods of exposure. Translation AIChE. 1935;31:365–389.
- Danckwerts PV. Significance of liquid-film coefficients in gas absorption. Industrial & Engineering Chemistry. 1951 Jun;43(6):1460–1467.
- Wren JC, Ball JM. LIRIC 3.2 an updated model for iodine behaviour in the presence of organic impurities. Radiation Physics and Chemistry. 2001;60(6):577–596.