Simulation of event‐based and long‐term spatial redistribution of Chernobyl‐derived radiocaesium within catchments using geographical information system embedded models

The Chernobyl accident contaminated vast areas of Europe with radiocaesium ( 137 Cs) in 1986. To evaluate long-term and event-based redistribution of Chernobyl-derived 137 Cs at the catchment scale, two geographical information system embedded models have been developed. The first model simulates 137 Cs redistribution using a monthly time step based on a long-term soil erosion model. The second model simulates lateral radiocaesium transport at the event scale based on the existing Limburg soil erosion model. This model accounts for surface runoff, soil erosion and deposition, and radiocaesium exchange between the topsoil layer, runoff water, and suspended sediment. Both models have been tested and applied to the Mochovce catchment, western Slovakia. The spatial distribution of 137 Cs activity in soil simulated by the long-term model was used as input for the event-based model to assess the changes in 137 Cs transport during rainfall events between 1986 and 2002. Soil erosion events in the first months after initial fallout input before ploughing caused a considerable decline in the 137 Cs soil inventories, which were estimated at 8.9% of the total initial inventory. The majority of 137 Cs transport during rainfall events occurs in particulate form. Both the absolute amounts of particulate 137 Cs transport and the fraction of particulate 137 Cs transport were shown to be positively related to suspended sediment transport. Between 1986 and 2002, dissolved 137 Cs transport has declined by a factor of about 26, which can be largely attributed to the increased sorption to sediment particles. Particulate 137 Cs transport has declined by a factor of about two, which can be largely attributed to the decrease in soil 137 Cs. The 137 Cs inventories in soil have decreased by a factor between three and four at the steep hillslopes, but have remained at about the same level as the initial fallout input at the valley bottoms.

[1]  William H. Blake,et al.  Use of 7Be and 137Cs measurements to document short‐ and medium‐term rates of water‐induced soil erosion on agricultural land , 1999 .

[2]  Mark J. Zheleznyak,et al.  Implementation of the Decision Support System for the River-Reservoir Network Affected by Releases from the Bohunice NPP, Slovakia , 1997 .

[3]  Giuseppe Giordano,et al.  Sediment delivery processes and the spatial distribution of caesium-137 in a small Sicilian basin , 1998 .

[4]  Francis R. Livens,et al.  Retention of radioactive caesium by different soils in the catchment of a small lake , 1993 .

[5]  A. D. Roo,et al.  LISEM: a single-event physically based hydrological and soil erosion model for drainage basins; I: theory, input and output , 1996 .

[6]  Jerry C. Ritchie,et al.  Application of Radioactive Fallout Cesium-137 for Measuring Soil Erosion and Sediment Accumulation Rates and Patterns: A Review , 1990 .

[7]  D. Walling,et al.  The effect of water erosion and tillage movement on hillslope profile development : a comparison of field observations and model results , 1993 .

[8]  A. Roo,et al.  The use of 137Cs as a tracer in an erosion study in south limburg (the Netherlands) and the influence of chernobyl fallout , 1991 .

[9]  P. Burrough,et al.  Environmental Mobility of Radiocaesium in the Pripyat Catchment, Ukraine/Belarus , 1999 .

[10]  Luigi Monte,et al.  Evaluation of radionuclide transfer functions from drainage basins of fresh water systems , 1995 .

[11]  David Favis-Mortlock,et al.  Evaluation of field-scale and catchment-scale soil erosion models , 1999 .

[12]  A. F. Nisbet,et al.  Predicting soil to plant transfer of radiocesium using soil characteristics , 1999 .

[13]  Derek Karssenberg,et al.  Integrating dynamic environmental models in GIS: The development of a Dynamic Modelling language , 1996, Trans. GIS.

[14]  A. Maes,et al.  Quantitative analysis of radiocaesium retention in soils , 1988, Nature.