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Ecosystem uptake and transfer of Sellafield-derived radiocarbon (14C). Part 1. The Irish Sea
Muir, G.K.P.; Tierney, K.M.; Cook, G.T.; MacKinnon, G.; Howe, J.A.; Heymans, J.J.; Hughes, D.J.; Xu, S. (2017). Ecosystem uptake and transfer of Sellafield-derived radiocarbon (14C). Part 1. The Irish Sea. Mar. Pollut. Bull. 114(2): 792-804. https://dx.doi.org/10.1016/j.marpolbul.2016.10.072
In: Marine Pollution Bulletin. Macmillan: London. ISSN 0025-326X; e-ISSN 1879-3363, more
Peer reviewed article  

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Keyword
    Marine/Coastal
Author keywords
    Sellafield; Radiocarbon (14C); Irish Sea; Biotic uptake; Seawater; Sediment

Authors  Top 
  • Muir, G.K.P.
  • Tierney, K.M.
  • Cook, G.T.
  • MacKinnon, G.
  • Howe, J.A.
  • Heymans, J.J., more
  • Hughes, D.J.
  • Xu, S.

Abstract
    Ecosystem uptake and transfer processes of Sellafield-derived radiocarbon (14C) within the Irish Sea were examined. Highly variable activities in sediment, seawater and biota indicate complex 14C dispersal and uptake dynamics. All east basin biota exhibited 14C enrichments above ambient background while most west basin biota had 14C activities close to background, although four organisms including two slow-moving species were significantly enriched. The western Irish Sea gyre is a suggested pathway for transfer of 14C to the west basin and retention therein. Despite ongoing Sellafield 14C discharges, organic sediments near Sellafield were significantly less enriched than associated benthic organisms. Rapid scavenging of labile, 14C-enriched organic material by organisms and mixing to depth of 14C-enriched detritus arriving at the sediment/water interface are proposed mechanisms to explain this. All commercially important fish, crustaceans and molluscs showed 14C enrichments above background; however, the radiation dose from their consumption is extremely low and radiologically insignificant.

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