R. Peridäfiez et al
Garnier-Laplace, J., Adam, C., Lathuilliere, T., Baudin, J., Clabaut, M., 2000, A simple
fish physiological model for radioecologists exemplified for 54Mn direct transfer
and rainbow trout (Oncorhynchus mykiss W). J. Environ. Radioact. 49, 35-53,
3leizon, P., McDonald, P., 2010. Modelling radioactivity in the Irish Sea: from discharge
to dose. J. Environ. Radioact, 101, 403-413,
‘3lover, D.M., Jenkins, W.J., Doney, S.C., 2011, Modelling Methods for Marine Science,
Cambridge University Press, UK,
3oshawk, J.A., Clarke, S., Smith, C.N., McDonald, P., 2003. MEAD (Part I): A
mathematical model of the long-term dispersion of radioactivity in shelf sea
environments. J. Environ. Radioact, 68, 115-135,
4aidvogel, D.B., Arango, H.G., Hedstrom, K., Beckmann, A,, Malanotte-Rizzoli, P.,
Shchepetkin, A.F., 2000, Model evaluation experiments in the North Atlantic Basin:
Simulations in nonlinear terrain-following coordinates. Dyn. Atmos, Oceans 32,
239-281.
Jarms, I.H., 1997, Modelling the dispersion of Cs-137 and Pu-239 released from
dumped waste in the Kara Sea. J, Mar, Syst. 13, 1-19,
arms, I.H., Karcher, M.J., Burchard, H., 2003, Modelling radioactivity in the marine
environment: the application of hydrodynamic circulation models for simulating
„ceanic dispersion of radioactivity. In: Scott, E.M. (Ed.), Modelling Radioactivity
in the Environment. Elsevier Science Ltd, Oxford, pp. 55-85.
Jarms, 1, Karcher, M.J., Dethleff, D., 2000. Modelling Siberian river runoff -
implications for contaminant transport in the Arctic Ocean, J, Mar, Syst. 27,
95-115.
4azell, D.R., England, M.H., 2003. Prediction of the fate of radioactive material in
the South Pacific Ocean using a global high-resolution ocean model. J, Environ,
Radioact. 65, 329-355.
4eling, R., Koziy, L., Bulgakov, V., 2002, On the dynamical uptake model developed
for the uptake of radionuclides in marine organisms for the POSEIDON-R model
system. Radioprotection 37 (C1), 833-838,
4erzfeld, M., Schmidt, M., Griffies, S.M., Liang, Z., 2011. Realistic test cases for limited
area ocean modelling. Ocean Model. 37, 1-34,
Higashi, H., Morino, Y,, Furuichi, N., Ohara, T., 2015. Ocean dynamic processes causing
spatially heterogeneous distribution of sedimentary caesium-137 massively released
from the Fukushima Dalichi Nuclear Power Plant. Biogeosciences 12, 7107-7128.
‘Jonda, M., Aono, T., Aoyama, M., Hamajima, Y., Kawakami, H., Kitamura, M.,
Masumoto, Y., Miyazawa, Y., Takigawa, M., Saino, T., 2012, Dispersion of artificial
snesium-134 and -137 in the western North Pacific one month after the Fukushima
accident. Geochem., J. 46, 1-9,
4äkanson, L., 2005. A new general dynamic model predieting radionuclide concen-
rrations and fluxes in coastal areas from readily accessible driving variables, J.
Environ, Radioact. 78, 217-245.
3Zunt, G.J., 2004. Radiological assessment of ocean radioactivity. In: Livingston, H.
(Ed.), Marine Radioactivity. Elsevier, Amsterdam, pp. 205-236.
'AEA, 1995, Validation of models using Chernobyl fallout data from the Central
Bohemia region of the Czech Republic. Scenario CB, First report of the VAMP
Multiple Pathways Assessment Working Group, JAEA-TECDOC-795, Vienna.
[AEA, 2000. Modelling of the transfer of radiocaesium from deposition to lake
acosystems, Report of the VAMP Aquatic Working Group. JAEA-TECDOC-1143.
Vienna,
{AEA, Sediment Distribution Coefficients and Concentration Factors for Biota in the
Marine Environment. Technical Reports Series, vol. 422, Vienna,
losjpe, M., Brown, J., Strand, P., 2002. Modified approach for box modelling of
radiological consequences from releases into marine environment. J. Environ,
Radioact, 60 (1-2), 91-103.
osjpe, M., Karcher, M., Gwynn, J., Harms, [., Gerdes, R., Kauker, F., 2009. Improvement
of the dose assessment tools on the basis of dispersion of the *°Tc in the Nordic
Seas and the Arctic Ocean, Radioprotection 44 (5), 531-536.
‚James, 1.D., 2002. Modelling pollution dispersion, the ecosystem and water quality in
coastal waters: a review. Environ, Model. Softw. 17, 363-385.
jayne, S.R., Hogg, N.G., Waterman, S.N., Rainville, L,., Donohue, K.A., Ran-
dolph Watts, D., Tracey, K.L., McClean, J.L., Maltrud, M.E., Qiu, B., Chen, S,,
2009. The kuroshio extension and its recirculation gyres. Deep Sea Res. I 56 (12),
2088-2099,
Johansson, H., Lindström, M., Häkanson, L., 2001. On the modelling of the particulate
and dissolved fractions of substances in aquatic ecosystems - sedimentological and
ecological interactions. Ecol. Model. 137, 225-240.
Kaeriyama, H., 2017, Oceanic dispersion of Fukushima-derived radioactive cesium: a
review, Fisheries Oceanography 26 (2), 99-113.
Kampf, J., 2009. Ocean Modelling for Beginners, Springer-Verlag, Heidelberg.
Kampf, J., 2010. Advanced Ocean Modelling. Springer-Verlag, Heidelberg.
Xanda, J., 2013. Continuing !37Cs release to the sea from the Fukushima Dai-Ichi
Nuclear Power Plant through 2012. Biogeosciences 10, 6107-6113.
Kauler, F., Kaminski, T., Karcher, M., Dowdall, M., Brown, J., Hosseini, A., Strand, P.,
2016. Model analysis of worst place scenarios for nuclear accidents in the northern
marine environment. Environ. Model. Softw. 77, 13-18,
Kawamura, H., Furuno, A., Kobayashi, T., In, T., Nakayama, T., Ishikawa, Y.,
Miyazawa, Y., Usui, N., 2017. Oceanic dispersion of Fukushima-derived Cs-137
simulated by multiple oceanic general circulation models, J. Environ, Radioact,
180, 36-58.
Environmental Modelling and Software 122 (2019) 104523
Kawamura, H., Kobayashi, T., Furuno, A., In, T., Ishikawa, Y., Nakayama, T., Shima, S.,
Awaji, T., 2011. Preliminary numerical experiments on oceanic dispersion of 31
and !37Cs discharged into the ocean because of the Fukushima Daiichi muclear
power plant disaster. J. Nucl, Sci. Technol. 48, 1349-1356.
Kawamura, H., Kobayashi, T., Furuno, A., Usui, N., Kamachi, M., 2014. Numerical
simulation on the long-term variation of radioactive cesium concentration in the
North Pacific due to the Fukushima disaster. J. Environ. Radioact, 136, 64-75.
Kobayashi, T., Kawamura, H., Fujli, K., Kamidaira, Y., 2017. Development of a short-
term emergency assessment system of the marine environmental radioactivity
around Japan. J. Nucl. Sci. Technol. 54, 609-616.
Kobayashi, T., Nagai, H., Chino, M., Kawamura, H., 2013, Source term estimation of
atmospheric release due to the Fukushima Dai-ichi Nuclear Power Plant accident by
atmospheric and oceanic dispersion simulations. J. Nucl. Sci. Technol. 50, 255-264.
Kobayashi, T., Otosaka, S., Togawa, O., Hayashi, K., 2007. Development of a non-
conservative radionuclides dispersion model in the ocean and its application to
surface cesium-137 dispersion in the Irish Sea. J, Nucl. Sci. Technol. 44 (2)
238-247.
Konovalenko, L., Bradshaw, C., Kumblad, L., Kautsky, U., 2014. Radionuclide transfer
in marine coastal ecosystems, a modelling study using metabolic processes and site
data. J. Environ, Radioact, 133, 48-59,
Kowalik, Z., Murty, T.S., 1993, Numerical Modelling of Ocean Dynamics. World
Scientific, Singapore.
Koziy, L., Maderich, V., Margvelashvili, N., Zheleznyak, M., 1998, Three-dimensional
model of radionuclide dispersion in the estuaries and shelf seas. Environ, Model.
Softw. 13, 413-420.
Laissaoui, A., Abril, J.M., Periäßez, R., Garcfa-Le6n, M., Garcla-Montafio, E., 1998.
Kinetic transfer coefficients for radionuclides in estuarine waters: reference valuer
for 133Ba and effects of salinity and suspended load concentration. J. Radioanal.
Nucl, Chem. 237, 55-61.
Lepicard, S., Heling, R., Maderich, V., 2004. POSEIDON/RODOS model for radiological
assessment of marine environment after accidental releases: application to coastal
areas of the Baltic, Black and North seas. J. Environ, Radioact. 72 (1-2), 153-161.
Lepicard, S., Raffestin, D., Rancillac, F., 1998, Poseidon: a dispersion computer code
for assessing radiological i mpacts in a European sea water environment. Radiat.
Prot. Dosim. 75, 79-83.
Lick, W., 2008. Sediment and Contaminant Transport in Surface Waters, CRC Press,
Lynch, D.R., Greenberg, D.A., Bilgili, A., Megillicuddy, D.J., Manning, J.P., Aretx-
abaleta, A.L., 2015, Particles in the Coastal Ocean, Theory and Applications
Cambridge University Press, NY,
iyons, M.G., Bradley, 5.B., Parker, T.G., 1998. Developments in the CUMBRIA model
and its application to radiological assessment in the Irish Sea, Radiat. Prot. Dosim.
75, 91-97,
Maderich, V., 1998. Modelling of the Mediterranean system: changes under climate
variations and man-made impact. Environ. Model. Softw. 13 (5-6), 405-412.
Maderich, V., Bezhenar, R., Heling, R., de With, G., Jung, K.T., Myoung, J.G., Cho, Y.K.,
Qiao, F., Robertson, L., 2014a. Regional long-term model of radivactivity dispersion
and fate in the northwestern Pacific and adjacent seas: application to the Fukushima
Dai-ichi aceident. J. Environ. Radioact. 131, 4-18.
Maderich, V., Brovchenko, I., Dvorzhak, A., Koshebutsky, V., Perläfiez, R., 2016.
Integration of 3D model THREETOX in JRODOS, implementation studies and
modelling of Fukushima scenarios. Radioprotection 51, 5133-5135.
Maderich, V., Heling, R., Bezhenar, R., Brovchenko, [., Jenner, H., Koshebutskyy, V.,
Kuschan, A., K., Terletska, 2008. Development and application of 3D numerical
model THREETOX to the prediction of cooling water transport and mixing in the
Inland and coastal waters. Hydrol. Process, 22, 1000-1013,
Maderich, V., Jung, K.T., Bezhenar, R., de With, G., Qiao, F., Casacuberta, N.,
Masque, P., Kim, Y.H., 2014b. Dispersion and fate of ”Sr in the Northwestern
Pacific and adjacent seas: Global fallout and the Fukushima Dai-ichi accident. Sci.
Total Environ, 494-495, 261-271.
Maderich, V., Jung, K.T., Brovchenko, I, Kim, K.O., 2017, Migration of radioactivity
in multi-fraction sediments. Environ. Fluid Mech. 17, 1207-1231,
Madigan, D.J., Baumann, Z., Fisher, N,S., 2012. Pacific bluefin tuna transport
Fukushima-derived radionuclides from Japan to California. Proc. Natl. Acad. Sci.
109, 9483-9486.
Margvelashvily, N., Maderich, V., Zheleznyak, M., 1997. THREETOX - computer code
to simulate three-dimensional dispersion of radionuclides in homogeneous and
stratified water bodies. Radiat, Prot. Dosim. 73, 177-180,
Masumoto, Y., Miyazawa, Y., Tsumune, D., Kobayashi, T., Estournel, C., Marsaleix, P.,
Lanerolle, L., Mehra, A., Garraffo, Z.D., 2012. Oceanic dispersion simulation of
Cesium-137 from Fukushima Dai-ichi nuclear power plant, Elements 8, 207-212.
Masumoto, Y., Sasaki, H., Kagimoto, T., Komori, N., Ishida, A., Sasai, Y., Miyama, T.,
Motoi, T., Mitsudera, H., Takahashi, K., Sakuma, H., Yagamata, T., 2004. A fifty-
year eddy-resolving simulation of the world ocean - preliminary outcomes of OFES
(OGCM for the earth simulator). J. Earth Simul. 1, 36-56.
Miller, R.N., 2007. Numerical Modelling of Ocean Circulation. Cambridge University
Press, Uk.
Min, B.L., Perläfiez, R., Kim, 1,G., Suh, K.S., 2013, Marine dispersion assessment of 197Cs
released from the Fukushima nuclear accident. Mar, Pollut. Bull. 72, 22-33,
