Modelling the biogeochemical effects of heterotrophic and autotrophic N-2 fixation in the Gulf of Aqaba (Israel), Red Sea

TitleModelling the biogeochemical effects of heterotrophic and autotrophic N-2 fixation in the Gulf of Aqaba (Israel), Red Sea
Publication TypeJournal Article
Year of Publication2018
AuthorsKuhn A.M, Fennel K., Berman-Frank I.
JournalBiogeosciences
Volume15
Pagination7379-7401
Date Published2018/12
Type of ArticleArticle
ISBN Number1726-4170
Accession NumberWOS:000453228300001
Keywordsassimilation efficiency; cyanobacterium trichodesmium; dissolved-oxygen; dynamics; Environmental Sciences & Ecology; extensive bloom; Geology; marine ecosystem model; nitrogen-fixing microorganisms; north-atlantic; ocean acidification; phytoplankton; Primary productivity
Abstract

Recent studies demonstrate that marine N-2 fixation can be carried out without light by heterotrophic N-2 fixers (diazotrophs). However, direct measurements of N-2 fixation in aphotic environments are relatively scarce. Heterotrophic as well as unicellular and colonial photoautotrophic diazotrophs are present in the oligotrophic Gulf of Aqaba (northern Red Sea). This study evaluates the relative importance of these different diazotrophs by combining biogeochemical models with time series measurements at a 700 m deep monitoring station in the Gulf of Aqaba. At this location, an excess of nitrate, relative to phosphate, is present throughout most of the water column and especially in deep waters during stratified conditions. A relative excess of phosphate occurs only at the water surface during nutrient-starved conditions in summer. We show that a model without N-2 fixation can replicate the observed surface chlorophyll but fails to accurately simulate inorganic nutrient concentrations throughout the water column. Models with N-2 fixation improve simulated deep nitrate by enriching sinking organic matter in nitrogen, suggesting that N-2 fixation is necessary to explain the observations. The observed vertical structure of nutrient ratios and oxygen is reproduced best with a model that includes heterotrophic as well as colonial and unicellular autotrophic diazotrophs. These results suggest that heterotrophic N-2 fixation contributes to the observed excess nitrogen in deep water at this location. If heterotrophic diazotrophs are generally present in oligotrophic ocean regions, their consideration would increase current estimates of global N-2 fixation and may require explicit representation in large-scale models.

DOI10.5194/bg-15-7379-2018
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