Future Arctic Ocean primary productivity from CMIP5 simulations: Uncertain outcome, but consistent mechanisms
Future Arctic Ocean primary productivity from CMIP5 simulations: Uncertain outcome, but consistent mechanisms
Net Arctic Ocean primary production (PP) is expected to increase over this century, due to less perennial sea ice and more available light, but could decrease depending on changes in nitrate (NO3) supply. Here Coupled Model Intercomparison Project Phase 5 simulations performed with 11 Earth System Models are analyzed in terms of PP, surface NO3, and sea ice coverage over 1900–2100. Whereas the mean model simulates reasonably well Arctic-integrated PP (511?TgC/yr, 1998–2005) and projects a mild 58?TgC/yr increase by 2080–2099 for the strongest climate change scenario, models do not agree on the sign of future PP change. However, similar mechanisms operate in all models. The perennial ice loss-driven increase in PP is in most models NO3-limited. The Arctic surface NO3 is decreasing over the 21st century (?2.3?±?1?mmol/m3), associated with shoaling mixed layer and with decreasing NO3 in the nearby North Atlantic and Pacific waters. However, the intermodel spread in the degree of NO3 limitation is initially high, resulting from >1000?year spin-up simulations. This initial NO3 spread, combined with the trend, causes a large variation in the timing of oligotrophy onset—which directly controls the sign of future PP change. Virtually all models agree in the open ocean zones on more spatially integrated PP and less PP per unit area. The source of model uncertainty is located in the sea ice zone, where a subtle balance between light and nutrient limitations determines the PP change. Hence, it is argued that reducing uncertainty on present Arctic NO3 in the sea ice zone would render Arctic PP projections much more consistent.
Arctic, primary production, nitrate, sea ice
605-619
Vancoppenolle, Martin
c48d03ee-16ea-4e82-9119-c38d79093714
Bopp, Laurent
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Madec, Gurvan
ffb28deb-4bbd-4a4c-914f-492f813e4864
Dunne, John
d7130a2c-8122-4296-897a-f5767c9d834e
Ilyina, Tatiana
1f1d00ed-8ce3-4e6d-a893-42dc3b14c18d
Halloran, Paul R.
fc3fb311-de73-4fd8-a0f2-dd18e9187b8e
Steiner, Nadja
3692ec3d-7e95-4823-aace-03b9b270f4e0
September 2013
Vancoppenolle, Martin
c48d03ee-16ea-4e82-9119-c38d79093714
Bopp, Laurent
771de655-3caf-42ba-8231-40f17d4addc4
Madec, Gurvan
ffb28deb-4bbd-4a4c-914f-492f813e4864
Dunne, John
d7130a2c-8122-4296-897a-f5767c9d834e
Ilyina, Tatiana
1f1d00ed-8ce3-4e6d-a893-42dc3b14c18d
Halloran, Paul R.
fc3fb311-de73-4fd8-a0f2-dd18e9187b8e
Steiner, Nadja
3692ec3d-7e95-4823-aace-03b9b270f4e0
Vancoppenolle, Martin, Bopp, Laurent, Madec, Gurvan, Dunne, John, Ilyina, Tatiana, Halloran, Paul R. and Steiner, Nadja
(2013)
Future Arctic Ocean primary productivity from CMIP5 simulations: Uncertain outcome, but consistent mechanisms.
Global Biogeochemical Cycles, 27 (3), .
(doi:10.1002/gbc.20055).
Abstract
Net Arctic Ocean primary production (PP) is expected to increase over this century, due to less perennial sea ice and more available light, but could decrease depending on changes in nitrate (NO3) supply. Here Coupled Model Intercomparison Project Phase 5 simulations performed with 11 Earth System Models are analyzed in terms of PP, surface NO3, and sea ice coverage over 1900–2100. Whereas the mean model simulates reasonably well Arctic-integrated PP (511?TgC/yr, 1998–2005) and projects a mild 58?TgC/yr increase by 2080–2099 for the strongest climate change scenario, models do not agree on the sign of future PP change. However, similar mechanisms operate in all models. The perennial ice loss-driven increase in PP is in most models NO3-limited. The Arctic surface NO3 is decreasing over the 21st century (?2.3?±?1?mmol/m3), associated with shoaling mixed layer and with decreasing NO3 in the nearby North Atlantic and Pacific waters. However, the intermodel spread in the degree of NO3 limitation is initially high, resulting from >1000?year spin-up simulations. This initial NO3 spread, combined with the trend, causes a large variation in the timing of oligotrophy onset—which directly controls the sign of future PP change. Virtually all models agree in the open ocean zones on more spatially integrated PP and less PP per unit area. The source of model uncertainty is located in the sea ice zone, where a subtle balance between light and nutrient limitations determines the PP change. Hence, it is argued that reducing uncertainty on present Arctic NO3 in the sea ice zone would render Arctic PP projections much more consistent.
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Published date: September 2013
Keywords:
Arctic, primary production, nitrate, sea ice
Organisations:
Marine Systems Modelling
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Local EPrints ID: 359557
URI: http://eprints.soton.ac.uk/id/eprint/359557
ISSN: 0886-6236
PURE UUID: b71f2bd6-0711-40a6-ad2d-a18bb82f4d3c
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Date deposited: 04 Nov 2013 12:00
Last modified: 14 Mar 2024 15:24
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Author:
Martin Vancoppenolle
Author:
Laurent Bopp
Author:
Gurvan Madec
Author:
John Dunne
Author:
Tatiana Ilyina
Author:
Paul R. Halloran
Author:
Nadja Steiner
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