Inter-comparison of dynamic models for radionuclide transfer to marine biota in a Fukushima accident scenario

Research output: Contribution to journalArticlepeer-review


  • Nicholas Beresford
  • Karine Beaugelin-Seiller
  • Roman Bezhenar
  • Justin Brown
  • Jing-Jy Cheng
  • Mirjana Cujic
  • Snezana Dragovic
  • Céline Duffa
  • Bruno Fievet
  • Ali Hosseini
  • Kyung Tae Jung
  • Sunita Kamboj
  • Dong-Kwon Keum
  • Alexander Kryshev
  • David LePoire
  • Vladimir Maderich
  • Byung Il Min
  • Raúl Periáñez
  • Tatiana Sazykina
  • Kyung-Suk Suh
  • Charley Yu
  • Cheng Wang
  • Rudie Heling

Institutes & Expert groups

  • NERC-CEH - Natural Environment Research Council : Centre for Ecology and Hydrology
  • IRSN - Institute for Radioprotection and Nuclear Safety - Institut Radioprotection Sûreté Nucléaire
  • IMMSP - Institute of Mathematical Machine and System Proplems - Ukraine
  • NPRA - Norwegian Radiation Protection Authority
  • Argonne National Laboratory
  • University of Belgrade - Vinča Institute of Nuclear Sciences
  • KIOST - Korean Institute of Ocean Science and Technology
  • KAERI - Korea Atomic Energy Research Institute
  • Research and Production Association "Typhoon"
  • US - University of Seville
  • NRG - Nuclear Research and Consultancy Group

Documents & links


We report an inter-comparison of eight models designed to predict the radiological exposure of radionuclides in marine biota. The models were required to simulate dynamically the uptake and turnover of radionuclides by marine organisms. Model predictions of radionuclide uptake and turnover using kinetic calculations based on biological half-life (TB1/2) and/or more complex metabolic modelling approaches were used to predict activity concentrations and, consequently, dose rates of 90Sr, 131I and 137Cs to fish, crustaceans, macroalgae and molluscs under circumstances where the water concentrations are changing with time. For comparison, the ERICA Tool, a model commonly used in environmental assessment, and which uses equilibrium concentration ratios, was also used. As input to the models we used hydrodynamic forecasts of water and sediment activity concentrations using a simulated scenario reflecting the Fukushima accident releases. Although model variability is important, the intercomparison gives logical results, in that the dynamic models predict consistently a pattern of delayed rise of activity concentration in biota and slow decline instead of the instantaneous equilibrium with the activity concentration in seawater predicted by the ERICA Tool. The differences between ERICA and the dynamic models increase the shorter the TB1/2 becomes; however, there is significant variability between models, underpinned by parameter and methodological differences between them. The need to validate the dynamic models used in this intercomparison has been highlighted, particularly in regards to optimisation of the model biokinetic parameters.


Original languageEnglish
Pages (from-to)31-50
Number of pages20
JournalJournal of environmental radioactivity
Publication statusPublished - 1 Mar 2016


  • dynamic model, MODARIA, Non-human biota, Dose

ID: 835862