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A numerical model of seasonal primary production within the Chukchi/Beaufort Seas

A numerical model of seasonal primary production within the Chukchi/Beaufort Seas
A numerical model of seasonal primary production within the Chukchi/Beaufort Seas
A coupled three-dimensional circulation and ecological model provided numerical analysis of daily carbon/nitrogen cycling by the planktonic and benthic components of western Arctic shelf/basin ecosystems during 2002, when extensive field data were obtained by American and Canadian ice-breakers. Seasonal model budgets of April–May, July–August, and September–October 2002 allowed both interpolation and extrapolation of these validation data, suggesting that the most productive shelf regime of the Chukchi/Beaufort Seas was that of summer. Yet, during this period of July–August, a combination of light-limitation and nutrient-limitation limited shelf-wide mean simulated net photosynthesis to only 709mg Cm2 day 1 for shelf waters of o220m depth. This modeled seasonal carbon fixation then accounted for 45% of the annual shelf primary production of 97.4g Cm 2 yr 1. Identification of the relative importance of natural control factors of light and nutrients by the coupled model provided insight into possible consequences of future global climatic changes at these high latitudes.

The model’s seasonal penetration of relatively saline, nutrient-rich Anadyr Water of Pacific origin into the eastern Chukchi Sea replicated the time series of observed salinity fields. A similar fidelity of the simulated nitrate, silicate and dissolved inorganic carbon fields with the observed ones yielded an assessment of nutrient uptake and photosynthesis during a natural fertilization experiment. The simulated chlorophyll, dissolved organic carbon (DOC), and NH4 stocks also mimicked these shipboard observations. We found that the spring 2002 stocks of new nutrients were stripped by the end of summer, with little fall nutrient resupply by physical and biotic factors, when incident light waned. However, because of extensive ice cover and nutrient-poor upper waters within the Canadian Basin, the slope regions remained oligotrophic throughout the year, yielding a simulated annual net photosynthesis of 50g Cm 2 yr 1. We conclude that future ice cover retreat, without eutrophication, may have little impact on increased carbon sequestration within these high-latitude ecosystems.
0967-0645
3541-3576
Walsh, John J.
034b52e2-9bfd-4474-97cc-84524fe056f0
Dieterle, Dwight A.
b3c06607-40d3-4fdc-81fd-67f9b5b1b943
Maslowski, Wieslaw
f8b2588d-e021-485a-b74f-fc8e3fe38652
Grebmeier, Jacqueline M.
64b5f071-1b80-44d5-b821-49ca4ed1daa1
Whitledge, Terry E.
4737633c-4f2b-48aa-8836-270720df9603
Flint, Mikhail
60e18f5a-d957-4102-9104-b8602f302b6f
Sukhanova, Irina N.
077c34fc-f028-45ab-8568-3acd211a3869
Bates, Nicholas
954a83d6-8424-49e9-8acd-e606221c9c57
Cota, Glenn F.
39185b1e-4ebb-4662-8298-9bd68b65a268
Stockwell, Dean
01fe4d3b-1dfa-48fd-985c-09f78909f139
Moran, S.B.
d51ee82a-f1da-42f9-8f1f-2b37fa42e1ac
Hansell, Dennis A.
d4f0a3af-ca20-4791-a794-e52cbd56d654
McRoy, C. Peter
79404693-3e44-4417-813e-fa718b4e94af
Walsh, John J.
034b52e2-9bfd-4474-97cc-84524fe056f0
Dieterle, Dwight A.
b3c06607-40d3-4fdc-81fd-67f9b5b1b943
Maslowski, Wieslaw
f8b2588d-e021-485a-b74f-fc8e3fe38652
Grebmeier, Jacqueline M.
64b5f071-1b80-44d5-b821-49ca4ed1daa1
Whitledge, Terry E.
4737633c-4f2b-48aa-8836-270720df9603
Flint, Mikhail
60e18f5a-d957-4102-9104-b8602f302b6f
Sukhanova, Irina N.
077c34fc-f028-45ab-8568-3acd211a3869
Bates, Nicholas
954a83d6-8424-49e9-8acd-e606221c9c57
Cota, Glenn F.
39185b1e-4ebb-4662-8298-9bd68b65a268
Stockwell, Dean
01fe4d3b-1dfa-48fd-985c-09f78909f139
Moran, S.B.
d51ee82a-f1da-42f9-8f1f-2b37fa42e1ac
Hansell, Dennis A.
d4f0a3af-ca20-4791-a794-e52cbd56d654
McRoy, C. Peter
79404693-3e44-4417-813e-fa718b4e94af

Walsh, John J., Dieterle, Dwight A., Maslowski, Wieslaw, Grebmeier, Jacqueline M., Whitledge, Terry E., Flint, Mikhail, Sukhanova, Irina N., Bates, Nicholas, Cota, Glenn F., Stockwell, Dean, Moran, S.B., Hansell, Dennis A. and McRoy, C. Peter (2005) A numerical model of seasonal primary production within the Chukchi/Beaufort Seas. Deep Sea Research Part II: Topical Studies in Oceanography, 52 (24-26), 3541-3576. (doi:10.1016/j.dsr2.2005.09.009).

Record type: Article

Abstract

A coupled three-dimensional circulation and ecological model provided numerical analysis of daily carbon/nitrogen cycling by the planktonic and benthic components of western Arctic shelf/basin ecosystems during 2002, when extensive field data were obtained by American and Canadian ice-breakers. Seasonal model budgets of April–May, July–August, and September–October 2002 allowed both interpolation and extrapolation of these validation data, suggesting that the most productive shelf regime of the Chukchi/Beaufort Seas was that of summer. Yet, during this period of July–August, a combination of light-limitation and nutrient-limitation limited shelf-wide mean simulated net photosynthesis to only 709mg Cm2 day 1 for shelf waters of o220m depth. This modeled seasonal carbon fixation then accounted for 45% of the annual shelf primary production of 97.4g Cm 2 yr 1. Identification of the relative importance of natural control factors of light and nutrients by the coupled model provided insight into possible consequences of future global climatic changes at these high latitudes.

The model’s seasonal penetration of relatively saline, nutrient-rich Anadyr Water of Pacific origin into the eastern Chukchi Sea replicated the time series of observed salinity fields. A similar fidelity of the simulated nitrate, silicate and dissolved inorganic carbon fields with the observed ones yielded an assessment of nutrient uptake and photosynthesis during a natural fertilization experiment. The simulated chlorophyll, dissolved organic carbon (DOC), and NH4 stocks also mimicked these shipboard observations. We found that the spring 2002 stocks of new nutrients were stripped by the end of summer, with little fall nutrient resupply by physical and biotic factors, when incident light waned. However, because of extensive ice cover and nutrient-poor upper waters within the Canadian Basin, the slope regions remained oligotrophic throughout the year, yielding a simulated annual net photosynthesis of 50g Cm 2 yr 1. We conclude that future ice cover retreat, without eutrophication, may have little impact on increased carbon sequestration within these high-latitude ecosystems.

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Published date: 2005
Organisations: Ocean Biochemistry & Ecosystems

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Local EPrints ID: 358272
URI: http://eprints.soton.ac.uk/id/eprint/358272
ISSN: 0967-0645
PURE UUID: 9df114a8-8a07-466b-975c-a357233b059c

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Date deposited: 02 Oct 2013 15:13
Last modified: 14 Mar 2024 15:02

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Contributors

Author: John J. Walsh
Author: Dwight A. Dieterle
Author: Wieslaw Maslowski
Author: Jacqueline M. Grebmeier
Author: Terry E. Whitledge
Author: Mikhail Flint
Author: Irina N. Sukhanova
Author: Nicholas Bates
Author: Glenn F. Cota
Author: Dean Stockwell
Author: S.B. Moran
Author: Dennis A. Hansell
Author: C. Peter McRoy

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