Modern parameters of caesium-137 root uptake in natural and agricultural grass ecosystems of contaminated post-Chernobyl landscape, Russia

Year 2015, Volume: 4 Issue: 1, 30 - 37, 08.01.2015

Tatiana Paramonova Ekaterina Machaeva Belyaev Vladimir

https://doi.org/10.18393/ejss.56716

Cited By: 2

Abstract

The estimation of modern parameters of ¹³⁷Cs root uptake was conducted in natural meadow and agricultural ecosystems of post-Chernobyl landscapes of Tula region. The agrosystems with main crops of field rotation (barley, potatoes, rape, maize) occupying watersheds and slopes with arable chernozems are contaminated at a level 460-670 Bq/kg (4.7-6.0 Ci/km²); natural meadow ecosystems occupying lower parts of slopes and floodplains are contaminated at a level 620-710 Bq/kg (5.8-7.6 Ci/km²). In the arable soils ¹³⁷Cs uniformly distributed to a depth of A_p horizon (20-30 cm of thickness), while in meadow soils 70-80% of the radionuclide is concentrated within the top A_d horizon (9-13 cm of thickness). These topsoil layer accords with rhizosphere zone, where >80-90% of plant roots are concentrated, and from which ¹³⁷Cs is mostly consumed by vegetation. Total amount of ¹³⁷Cs root uptake depends on the level of soil radioactive contamination (correlation coefficient 0.61). So ¹³⁷Cs activity in meadow vegetation (103-160 Bq/kg) is generally more than one in agricultural vegetation (9-92 Bq/kg). The values of ¹³⁷Cs transfer factor in the studied ecosystems vary from 0.01 (rape) to 0.20 (wet meadow), that confirms the discrimination of the radionuclide’s root uptake. The larger are the volume of roots and their absorbing surface, the higher are the values of transfer factor from soil to plant (correlation coefficients 0.71 and 0.64 respectively). ¹³⁷Cs translocation from roots to shoots is also determined by biological features of plants. At the same level of soil contamination above-ground parts of meadow herbs accumulate more ¹³⁷Cs than Gramineae species, and in agrosystems above-ground parts of weeds concentrate more ¹³⁷Cs than cultivated cereals. Thus, the level of soil radioactive pollution and biological features of plants are determinants in the process of ¹³⁷Cs root uptake and translocation and should be considered in land use policy.

Keywords

radioactive contamination, caesium-137, root uptake, transfer factor, Chernobyl accident

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