Ecosystem model-based approach for modeling the dynamics of Cs-137 transfer to marine plankton populations: application to the western North Pacific Ocean after the Fukushima nuclear power plant accident

摘要

Huge amounts of radionuclides, especially Cs-137, were released into the western North Pacific Ocean after the Fukushima nuclear power plant (FNPP) accident that occurred on 11 March 2011, resulting in contamination of the marine biota. In this study we developed a radioecological model to estimate Cs-137 concentrations in phytoplankton and zooplankton populations representing the lower levels of the pelagic trophic chain. We coupled this model to a lower trophic level ecosystem model and an ocean circulation model to take into account the site-specific environmental conditions in the area. The different radioecological parameters of the model were estimated by calibration, and a sensitivity analysis to parameter uncertainties was carried out, showing a high sensitivity of the model results, especially to the Cs-137 concentration in seawater, to the rates of accumulation from water and to the radionuclide assimilation efficiency for zooplankton. The results of the Cs-137 concentrations in planktonic populations simulated in this study were then validated through comparison with the data available in the region after the accident. The model results have shown that the maximum concentrations in plankton after the accident were about 2 to 4 orders of magnitude higher than those observed before the accident, depending on the distance from FNPP. Finally, the maximum Cs-137 absorbed dose rate for phyto-and zooplankton populations was estimated to be about 5 x 10(-2) mu Gy h(-1), and was, therefore, lower than the predicted no-effect dose rate (PNEDR) value of 10 mu Gy h(-1) defined in the ERICA assessment approach.