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A global model of the marine ecosystem for long-term simulations: sensitivity to ocean mixing, buoyancy forcing, particle sinking, and dissolved organic matter cycling (2005)

Schmittner, A.

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In: Global biogeochemical cycles, Hoboken, NJ : Wiley, 1987, 19(2005), 1944-9224

In: volume:19

In: year:2005

In: extent:17

Type of Medium: Online Resource

Pages: 17

ISSN: 1944-9224

DOI: 10.1029/2004GB002283

Language: English

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Ecosystem dynamics based on plankton functional types for global ocean biogeochemistry models (2005)

Le Quéré, C. ; Harrison, S. P. ; Prentice, I. C. ; [et al.]

In: EPIC3Global Change Biology, 11, pp. 2016-2040

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Publication Date: 2019-07-17

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

Format: application/pdf

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Importance of coastal nutrient supply for global ocean biogeochemistry (2008)

Giraud, X. ; Le Quere, C. ; Cotrim da Cunha, Leticia

AGU (American Geophysical Union)

In: Global Biogeochemical Cycles, 22 (2). GB2025.

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Publication Date: 2018-03-20

Description: The coastal ocean provides nutrients to the open ocean in accounts that are poorly quantified. We use an ocean biogeochemistry model to assess the importance of the coastal nutrient supply to global ocean biogeochemistry. The model includes full cycles of P, Si, and Fe, as well as the representation of two phytoplankton groups, two zooplankton groups, and two organic detritus pools. When coastal mixing is enhanced to reproduce the action of tides and storms, primary production and chlorophyll‐a (Chla) concentrations show a large increase at the coast and a smaller increase in the open ocean. When coastal nutrient supply is enhanced to reproduce sediment resuspension or river supply, both the coastal ocean and the open ocean primary production and Chla concentration increase in comparable amounts. In agreement with the definition of nutrient limitation areas in the model, coastal export of P‐excess impacts mainly the subtropical oligotrophic areas, Si‐excess impacts the Arctic Ocean and some coastal areas, and Fe‐excess impacts the east equatorial Pacific, North Atlantic and North Pacific, and the Southern Ocean. Modeled Chla is closest to observations when the input ratio of Fe to P and Si is enhanced.

Type: Article , PeerReviewed

Format: text

DOI: 10.1029/2006GB002717

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A global model of the marine ecosystem for multi-millennial simulations (2005)

Schmittner, A. ; Oschlies, Andreas ; Giraud, X. ; [et al.]

AGU (American Geophysical Union)

In: Global Biogeochemical Cycles, 19 . GB3004.

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Publication Date: 2018-03-16

Description: A new model of the marine ecosystem coupled into a global Earth System Climate Model suitable for long-term (multimillennial timescale) simulations is presented. The model is based on nitrate as the sole limiting nutrient. Prognostic equations for nutrients, phytoplankton, zooplankton, and detritus are solved online in the three-dimensional ocean circulation model component. Experiments with different parameterizations of vertical mixing, including a scheme of tidally driven mixing, changes in buoyancy forcing in the Southern Ocean, different particle sinking velocities, and the inclusion of dissolved organic matter are performed, and the results are compared with observations. The results reemphasize the roles of Southern Ocean freshwater forcing and diapycnal mixing in the low-latitude pycnocline in setting the global deep water circulation and properties. The influence of high mixing in the Southern Ocean as inferred from observations is much more limited. The deep water circulation also has a strong influence on the marine ecosystem and nutrient distributions. We demonstrate that larger values of vertical diffusion lead to a shallower nutricline due to increased upwelling. Export production and nutrient distributions respond sensitively to changes in mixing and to the ratio of particle sinking to remineralization in the upper ocean. The best fits to global measurements of temperature, salinity, deep ocean radiocarbon, mixed layer depth, nutrients, and chlorophyll are obtained for values of vertical mixing in the pycnocline of around 0.2–0.3 × 10−4 m2/s and for e-folding depth for particle remineralization of 100–200 m. A simple parameterization of dissolved organic matter dynamics increases primary production and nutrient concentrations in the upper ocean and improves chlorophyll distributions in the subtropical gyres but has no discernible influence on particulate export fluxes. Remaining model deficiencies are identified, and strategies for future model improvement are outlined.

Type: Article , PeerReviewed

Format: text

DOI: 10.1029/2004GB002283

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Potential impact of changes in river nutrient supply on global ocean biogeochemistry (2007)

Cotrim da Cunha, Leticia ; Buitenhuis, E. T. ; Le Quere, C. ; [et al.]

AGU (American Geophysical Union)

In: Global Biogeochemical Cycles, 21 (4). GB4007.

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Publication Date: 2018-03-20

Description: The growing world population increases the demand for water, energy, and land. This demand for natural resources impacts the transport of material and the supply of nutrients in the coastal ocean by rivers. We assess the potential impact of river N, Si, Fe, and organic carbon (OC) fluxes on the global and coastal ocean biogeochemistry, using an ocean biogeochemistry model and observations, in eight different scenarios. We assess two extreme scenarios, one with no river nutrients, corresponding to a complete stop of nutrient input by rivers, and one with high nutrient fluxes, corresponding to a world population of 12 billion people. Compared to today's scenario values, primary production (PP) changes from −5% to +5% for the open ocean, and from −16% to +5% for the coastal ocean. In the coastal ocean the impact of river nutrients on PP depends on regional nutrient limitation. River inputs have a larger impact on PP in areas where upwelling and high runoff are combined. The coastal ocean is typically N‐ or Si‐limited. River Fe not assimilated by the phytoplankton is exported to open ocean areas, and its fertilizing effect depletes coastal and open ocean surface waters from N and Si. The impact on PP is reflected on global ocean low‐O2 areas whose extent changes from −16% to +23% across the range of scenarios. River nutrients have a modest impact on the global ocean CO2 sink of up to 0.4 Pg C a−1, depending on the amount of inorganic and organic carbon transported by the rivers.

Type: Article , PeerReviewed

Format: text

DOI: 10.1029/2006GB002718

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