Effects of radionuclide contamination on leaf litter decomposition in the Chernobyl exclusion zone

The effects of radioactive contamination on ecosystem processes such as litter decomposition remain largely unknown. Because radionuclides accumulated in soil and plant biomass can be harmful for organisms, the functioning of ecosystems may be altered by radioactive contamination. Here, we tested th...

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Bibliographic Details
Published in:The Science of the total environment 2016-08, Vol.562, p.596-603
Main Authors: Bonzom, Jean-Marc, Hättenschwiler, Stephan, Lecomte-Pradines, Catherine, Chauvet, Eric, Gaschak, Sergey, Beaugelin-Seiller, Karine, Della-Vedova, Claire, Dubourg, Nicolas, Maksimenko, Andrey, Garnier-Laplace, Jacqueline, Adam-Guillermin, Christelle
Format: Article
Language:English
Subjects:
Decomposers
Dose rates
Ecology, environment
Ecosystem functioning
Ionizing radiation
Life Sciences
Nuclear accident
Pollution
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Summary:The effects of radioactive contamination on ecosystem processes such as litter decomposition remain largely unknown. Because radionuclides accumulated in soil and plant biomass can be harmful for organisms, the functioning of ecosystems may be altered by radioactive contamination. Here, we tested the hypothesis that decomposition is impaired by increasing levels of radioactivity in the environment by exposing uncontaminated leaf litter from silver birch and black alder at (i) eleven distant forest sites differing in ambient radiation levels (0.22–15μGyh−1) and (ii) along a short distance gradient of radioactive contamination (1.2–29μGyh−1) within a single forest in the Chernobyl exclusion zone. In addition to measuring ambient external dose rates, we estimated the average total dose rates (ATDRs) absorbed by decomposers for an accurate estimate of dose-induced ecological consequences of radioactive pollution. Taking into account potential confounding factors (soil pH, moisture, texture, and organic carbon content), the results from the eleven distant forest sites, and from the single forest, showed increased litter mass loss with increasing ATDRs from 0.3 to 150μGyh−1. This unexpected result may be due to (i) overcompensation of decomposer organisms exposed to radionuclides leading to a higher decomposer abundance (hormetic effect), and/or (ii) from preferred feeding by decomposers on the uncontaminated leaf litter used for our experiment compared to locally produced, contaminated leaf litter. Our data indicate that radio-contamination of forest ecosystems over more than two decades does not necessarily have detrimental effects on organic matter decay. However, further studies are needed to unravel the underlying mechanisms of the results reported here, in order to draw firmer conclusions on how radio-contamination affects decomposition and associated ecosystem processes. [Display omitted] •The effects of radioactivity on ecosystem processes are largely unknown.•Leaf litter decomposition was studied in Chernobyl exclusion zone.•Litter mass loss increased with decomposer organisms' total dose rate.•Ecosystem processes may recover faster from radioactive pollution than populations.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2016.04.006