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An improved model of carbon and nutrient dynamics in the microbial food web in marine enclosures

1998; Inter-Research Science Center; Volume: 14; Linguagem: Inglês

10.3354/ame014091

1616-1564

JG Baretta-Bekker, JW Baretta, AS Hansen, Bo Riemann,

Marine Biology and Ecology Research

AME Aquatic Microbial Ecology Contact the journal Facebook Twitter RSS Mailing List Subscribe to our mailing list via Mailchimp HomeLatest VolumeAbout the JournalEditorsSpecials AME 14:91-108 (1998) - doi:10.3354/ame014091 An improved model of carbon and nutrient dynamics in the microbial food web in marine enclosures J. G. Baretta-Bekker1,*, J. W. Baretta1, A. S. Hansen2, B. Riemann3 1Ecological Modelling Centre, Joint Department of Danish Hydraulic Institute and VKI, Agern Allé 5, DK-2970 Hørsholm, Denmark2VKI, Agern Allé 11, DK-2970 Hørsholm, Denmark 3National Environmental Research Institute, PO Box 358, Frederiksborgvej 399, DK-4000 Roskilde, Denmark *E-mail: hbb@vki.dk A description of an improved dynamic simulation model of a marine enclosure is given. New features in the model are the inclusion of picoalgae and mixotrophs; the ability of bacteria to take up dissolved inorganic nutrients directly; and, for the phytoplankton functional groups, the inclusion of luxury uptake and the decoupling of the nutrient uptake dynamics from carbon-assimilation dynamics. This last feature implies dynamically variable phosphorus/carbon and nitrogen/carbon ratios. The model was calibrated with experimental results from enclosure experiments carried out in Knebel Vig, a shallow microtidal land-locked fjord in Denmark, and verified with results from enclosure experiments in Hylsfjord, a deep and salinity-stratified Norwegian fjord. Both observations and model simulations showed dominance of a microbial food web in control enclosures with low productivity. In N- and P-enriched enclosures a classical food web developed, while an intermediate system was found in N-, P- and Si-enriched enclosures. Mixotrophic flagellates were most important in the nutrient-limited control enclosures where they accounted for 49% of the pigmented biomass and about 48% of the primary production. Lumping the mixotrophs in the simulation model with either the autotrophic or the heterotrophic functional groups reduced total primary production by 74%. Model-derived, time-averaged phosphorus budgets suggested that bacteria competed with algae for orthophosphate in the control enclosure, but not in the enclosure to which N and P had been added, where bacteria functioned as net mineralisers of phosphate. In the N, P and Si enclosure, bacteria took up only 10% of the amount of orthophosphate taken up by the primary producers, passing most of the organic phosphorus on to their grazers, the heterotrophic nanoflagellates, and mineralising only a small fraction directly. Inclusion of luxury nutrient uptake affected the simulation of the nutrient-enriched enclosures, while the decoupling of carbon and nutrient dynamics affected the simulation of the control enclosure. Without these 2 processes it was not possible to simulate the carbon and nutrient dynamics in the different enclosures adequately with the same parameterisation. Microbial food web · Luxury uptake · Nutrient uptake · Nutrient cycles · Ecosystem model · Mesocosm Full text in pdf format PreviousNextExport citation RSS - Facebook - Tweet - linkedIn Cited by Published in AME Vol. 14, No. 1. Publication date: January 02, 1998 Print ISSN: 0948-3055; Online ISSN: 1616-1564 Copyright © 1998 Inter-Research.