Chemosymbiont-dominated seafloor communities in modern and Cretaceous upwelling systems support a new, high-productivity variant of standard low-oxygen models

Faunal analysis of modern (Benguela upwelling system, Namibia) and ancient (upper Cretaceous, Israel) sedimentary records rich in organic matter, biogenic silica, carbonate, and phosphate indicates that, contrary to stereotypes of upwelling systems as dead zones, macrobenthic communities are present...

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Bibliographic Details
Published in:Geology (Boulder) 2015-11, Vol.43 (11), p.975-978
Main Authors: Edelman-Furstenberg, Yael, Kidwell, Susan M
Format: Article
Language:English
Subjects:
Africa
anaerobic environment
Asia
Atlantic Ocean
Benguela Current
biofacies
carbon
communities
Cretaceous
depositional environment
Evolution
Geological time
Invertebrata
Israel
Marine
marine environment
Mesozoic
Middle East
Mishash Formation
modern analogs
Mollusca
Mollusks
Namibia
Ocean bottom
organic carbon
Oxygen
phosphates
productivity
silica
South Atlantic
Southeast Atlantic
Southern Africa
Stratigraphy
Upper Cretaceous
upwelling
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Summary:Faunal analysis of modern (Benguela upwelling system, Namibia) and ancient (upper Cretaceous, Israel) sedimentary records rich in organic matter, biogenic silica, carbonate, and phosphate indicates that, contrary to stereotypes of upwelling systems as dead zones, macrobenthic communities are present but highly variable. Biofacies vary with distance from the upwelling core and as a function of both the supply of food to the seafloor and the oxygen demand it creates there: under a high organic supply, large-bodied chemosymbiotic bivalves dominate exaerobic and lower dysaerobic seafloors, and deposit feeders are abundant in upper dysaerobic and aerobic zones. Macrobenthic biofacies under upwelling thus contrast strongly with the overwhelmingly filter feeder-dominated biofacies encountered in the dark siliciclastic shales on which standard oxygen-restricted biofacies models have been based, and argue that, mechanistically, the low-oxygen conditions characterizing those shales reflect ordinary levels of water-column productivity and arise largely from water-column stratification. Our biofacies model requires testing in other upwelling records. However, we expect it to be robust and useful given the long evolutionary histories of the chemosymbiotic and deposit-feeding guilds, providing a new means for discriminating the relative roles of high organic flux and low ventilation in creating low-oxygen conditions at the seafloor.
ISSN:0091-7613
1943-2682
DOI:10.1130/G37017.1