Mudflat biota since the 1930s: change beyond return?

Where, since the 1980s, patchy and variable green algal mats are prevailing, distinct belts of an amphipod (Corophium volutator) and seagrass (Zostera spp.) had dominated in the 1930s. The zonation between tide marks has been mapped in a sheltered sedimentary bay in the Wadden Sea near the island of...

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Veröffentlicht in:	Helgoland marine research 2008-03, Vol.62 (1), p.13-22
Hauptverfasser:	Reise, Karsten, Herre, Elisabeth, Sturm, Manfred
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Sprache:	eng
Schlagworte:	Algae Amphipoda Arenicola marina climate change Corophium volutator Enteromorpha eutrophication Fucales Fucus vesiculosus habitats Hydrobia ulvae introduced species Littorina littorea Marine Marine biology mussels Mytilus edulis Nereis salt marshes seagrasses Studies surveys Ulva vegetation Zostera Zostera noltii
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creator	Reise, Karsten Herre, Elisabeth Sturm, Manfred
description	Where, since the 1980s, patchy and variable green algal mats are prevailing, distinct belts of an amphipod (Corophium volutator) and seagrass (Zostera spp.) had dominated in the 1930s. The zonation between tide marks has been mapped in a sheltered sedimentary bay in the Wadden Sea near the island of Sylt (coastal eastern North Sea). Maps on vegetation from 1924 and on selected macrobenthos from 1932 and 1934 are compared with biannual surveys conducted from 1988 to 2006. Rising high water levels and eutrophication are suggested to be major causes of the observed long-term changes. In front of a saltmarsh, a sandy beach developed and partly displaced former cyanobacterial mats. Advancing sandiness may have inhibited C. volutator and facilitated lugworms, Arenicola marina, in the upper tidal zone. A variable occurrence of green algal mats arising in the 1980s affected infauna and seagrass by smothering the biota underneath. This dissolved a coherent belt of Zostera noltii. In the lower tidal zone, natural disturbances had lasting effects on the occurrence of mussels with attached fucoid algae. The spectrum of species became enriched by alien species (13% of macrobenthic taxa). A reversal to habitat structure and biotic zonation of the 1920–1930s does not seem possible. Aliens, in combination with climate change, are expected to further divert the ecological pattern to new configurations.
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The spectrum of species became enriched by alien species (13% of macrobenthic taxa). A reversal to habitat structure and biotic zonation of the 1920–1930s does not seem possible. Aliens, in combination with climate change, are expected to further divert the ecological pattern to new configurations.</abstract><cop>Heidelberg</cop><pub>Springer-Verlag</pub><doi>10.1007/s10152-007-0087-2</doi><tpages>10</tpages><oa>free_for_read</oa></addata></record>
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subjects	Algae Amphipoda Arenicola marina climate change Corophium volutator Enteromorpha eutrophication Fucales Fucus vesiculosus habitats Hydrobia ulvae introduced species Littorina littorea Marine Marine biology mussels Mytilus edulis Nereis salt marshes seagrasses Studies surveys Ulva vegetation Zostera Zostera noltii
title	Mudflat biota since the 1930s: change beyond return?
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