Adaptation of FDMT to include process-based models and consider regional aspects following radionuclide deposition events

Sci Total Environ. 2024 Nov 25:953:175921. doi: 10.1016/j.scitotenv.2024.175921. Epub 2024 Sep 1.

Abstract

Experience from earlier nuclear accidents has clearly shown the need for maintaining and developing appropriate modelling capabilities. Dealing with complex issues such as human exposure following a nuclear accident necessitates the implementation of a set of interconnected models such as FDMT. FDMT is an integrated module within the two main European decision support systems for radiological emergency preparedness, ARGOS and JRODOS, to simulate the transfer of radionuclides along terrestrial food chains and to predict their activity concentrations in foodstuffs. In order to make the module more fit-for-purpose, FDMT has been implemented in a new modelling platform (ECOLEGO) which provides a high degree of flexibility with regard to conducting developmental work. This paper presents improvements in FDMT further through either the incorporation of new models or further elaboration of existing ones, as well as updates in default parameters. Models have also been made more fit-for-purpose through consideration of regional-specific parameters. Specific improvements include modelling developments related to dry deposition, radioactive particle weathering, radiocaesium transfer influenced by soil characteristics and, for a region-specific case, animal uptake. In addition, the paper presents new pathways and parameters (and updated values) to be considered for making FDMT more adapted for Norwegian conditions. Overall, the improvements made in the present work should significantly reduce the uncertainties associated with the outputs of the FDMT models.

Keywords: Emergency preparedness; Human foodchain; Modelling capabilities; Nuclear accident; Transfer modelling.

MeSH terms

  • Cesium Radioisotopes / analysis
  • Food Chain
  • Humans
  • Models, Theoretical
  • Norway
  • Radiation Monitoring / methods
  • Radioactive Hazard Release*
  • Radioisotopes / analysis

Substances

  • Radioisotopes
  • Cesium Radioisotopes