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Impact of climate change on the Baltic Sea ecosystem over the past 1,000 years
Kabel, K.; Moros, M.; Porsche, C.; Neumann, T.; Adolphi, F.; Andersen, T.J.; Siegel, H.; Gerth, M.; Leipe, T.; Jansen, E.; Sinninghe Damsté, J.S. (2012). Impact of climate change on the Baltic Sea ecosystem over the past 1,000 years. Nat. Clim. Chang. 2(12): 871-874. dx.doi.org/10.1038/NCLIMATE1595
In: Nature Climate Change. Nature Publishing Group: London. ISSN 1758-678X; e-ISSN 1758-6798, more
Peer reviewed article  

Available in  Authors 
    NIOZ: NIOZ files 257613

Authors  Top 
  • Kabel, K.
  • Moros, M.
  • Porsche, C.
  • Neumann, T.
  • Adolphi, F.
  • Andersen, T.J., more
  • Siegel, H.
  • Gerth, M.
  • Leipe, T.
  • Jansen, E.
  • Sinninghe Damsté, J.S., more

Abstract
    Climate change has a strong impact on ecosystem health, particularly in marginal seas(1) such as the Baltic, for example causing the spreading of anoxic areas (oxygen-free areas, the so-called dead zones) through strong feedbacks. Marked ecosystem changes in the Baltic Sea have been recorded in the sedimentary archive, but the reasons are not fully understood(2,3). Here we report an integrated study of high-resolution sediment records (past 1,000 years) in combination with an ecosystem modelling approach, providing new insights into the functioning of the Baltic Sea ecosystem under natural and human-influenced climatic changes. Between the Little Ice Age and the Modern Warm Period the surface water temperatures reconstructed using TEX86 palaeothermometry increased by similar to 2 degrees C. Simultaneously, the anoxic areas in the Baltic Sea began to expand significantly as evident from the accumulation of laminated sediments. Ecosystem model simulations support our findings of widespread oxic areas during the Little Ice Age. Backed up by the modelling results that take into account anthropogenic-influenced nutrient load scenarios, our results provide evidence that surface temperature changes strongly influence deepwater oxygenation. This highlights the risk of a continued spreading of anoxic areas during scenarios of continued climate warming in the future.

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