Climate change and ocean acidification impacts on lower trophic levels and the export of organic carbon to the deep ocean

Most future projections forecast significant and ongoing climate change during the 21st century, but with the severity of impacts dependent on efforts to restrain or reorganise human activity to limit carbon dioxide (CO 2 ) emissions. A major sink for atmospheric CO 2 , and a key source of biological resources, the World Ocean is widely anticipated to undergo profound physical and – via ocean acidification – chemical changes as direct and indirect results of these emissions. Given strong biophysical coupling, the marine biota is also expected to experience strong changes in response to this anthropogenic forcing. Here we examine the large-scale response of ocean biogeochemistry to climate and acidification impacts during the 21st century for Representative Concentration Pathways (RCPs) 2.6 and 8.5 using an intermediate complexity global ecosystem model, MEDUSA-2.0. The primary impact of future change lies in stratification-led declines in the availability of key nutrients in surface waters, which in turn leads to a global decrease (1990s vs. 2090s) in ocean productivity (−6.3%). This impact has knock-on consequences for the abundance of the low trophic level biogeochemical actors modelled by MEDUSA-2.0 (−5.8%), and these would be expected to similarly impact higher trophic level elements such as fisheries. Related impacts are found in the flux of organic material to seafloor communities (−40.7% at 1000 m), and in the volume of ocean suboxic zones (+12.5%). A sensitivity analysis removing an acidification feedback on calcification finds that change in this process significantly impacts benthic communities, suggesting that a~better understanding of the OA-sensitivity of calcifying organisms, and their role in ballasting sinking organic carbon, may significantly improve forecasting of these ecosystems. For all processes, there is geographical variability in change – for instance, productivity declines −21% in the Atlantic and increases +59% in the Arctic – and changes are much more pronounced under RCP 8.5 than the RCP 2.6 scenario.

[1]  Olivier Aumont,et al.  Response of diatoms distribution to global warming and potential implications: A global model study , 2005 .

[2]  David A. Siegel,et al.  Carbon‐based primary productivity modeling with vertically resolved photoacclimation , 2008 .

[3]  Scott C. Doney,et al.  Iron availability limits the ocean nitrogen inventory stabilizing feedbacks between marine denitrification and nitrogen fixation , 2007 .

[4]  D. Mackas Does blending of chlorophyll data bias temporal trend? , 2011, Nature.

[5]  John P. Dunne,et al.  A synthesis of global particle export from the surface ocean and cycling through the ocean interior and on the seafloor , 2007 .

[6]  Toby Tyrrell,et al.  Phytoplankton Calcification in a High-CO2 World , 2008, Science.

[7]  Ulf Riebesell,et al.  Reduced calcification of marine plankton in response to increased atmospheric CO2 , 2000, Nature.

[8]  Richard A. Feely,et al.  Impacts of ocean acidification on marine fauna and ecosystem processes , 2008 .

[9]  B. Worm,et al.  Boyce et al. reply , 2011, Nature.

[10]  Christoph Heinze,et al.  Simulating oceanic CaCO3 export production in the greenhouse , 2004 .

[11]  Thomas R. Anderson,et al.  Mechanisms controlling primary and new production in a global ecosystem model – Part I: Validation of the biological simulation , 2006 .

[12]  B. Worm,et al.  Integrating global chlorophyll data from 1890 to 2010 , 2012 .

[13]  Bas Eickhout,et al.  The importance of three centuries of land-use change for the global and regional terrestrial carbon cycle , 2009 .

[14]  Andreas Oschlies,et al.  Can we predict the direction of marine primary production change under global warming? , 2011 .

[15]  R. Bidigare,et al.  Is there a decline in marine phytoplankton? , 2011, Nature.

[16]  S. Doney,et al.  An intermediate complexity marine ecosystem model for the global domain , 2001 .

[17]  Thomas R. Anderson,et al.  MEDUSA-2.0: an intermediate complexity biogeochemical model of the marine carbon cycle for climate change and ocean acidification studies , 2013 .

[18]  Richard Sanders,et al.  Global patterns in efficiency of particulate organic carbon export and transfer to the deep ocean , 2012 .

[19]  Ulf Riebesell,et al.  Species‐specific responses of calcifying algae to changing seawater carbonate chemistry , 2006 .

[20]  David M. Karl,et al.  VERTEX: carbon cycling in the northeast Pacific , 1987 .

[21]  Michele Scardi,et al.  A comparison of global estimates of marine primary production from ocean color , 2006 .

[22]  C. S. Wong,et al.  Climatological mean and decadal change in surface ocean pCO2, and net seaair CO2 flux over the global oceans , 2009 .

[23]  Michel Crucifix,et al.  The new hadley centre climate model (HadGEM1) : Evaluation of coupled simulations , 2006 .

[24]  J. Sarmiento,et al.  Oceanic vertical exchange and new production: a comparison between models and observations , 2001 .

[25]  Andreas Oschlies,et al.  Future changes in climate, ocean circulation, ecosystems, and biogeochemical cycling simulated for a business‐as‐usual CO2 emission scenario until year 4000 AD , 2008 .

[26]  Valérie Dulière,et al.  On the representation of high latitude processes in the ORCA-LIM global coupled sea ice–ocean model , 2005 .

[27]  Fortunat Joos,et al.  Sensitivity of pelagic calcification to ocean acidification , 2011 .

[28]  David A. Siegel,et al.  Climate-driven trends in contemporary ocean productivity , 2006, Nature.

[29]  M. Maqueda,et al.  Sensitivity of a global sea ice model to the treatment of ice thermodynamics and dynamics , 1997 .

[30]  David M. Nelson,et al.  Simulation of upper-ocean biogeochemistry with a flexible-composition phytoplankton model: C, N and Si cycling and Fe limitation in the Southern Ocean , 2006 .

[31]  B. Worm,et al.  Global phytoplankton decline over the past century , 2010, Nature.

[32]  T. R. Anderson,et al.  Regional variability of acidification in the Arctic: a sea of contrasts , 2013 .

[33]  Richard A. Feely,et al.  A global ocean carbon climatology: Results from Global Data Analysis Project (GLODAP) , 2004 .

[34]  W. Hibler A Dynamic Thermodynamic Sea Ice Model , 1979 .

[35]  Scott C. Doney,et al.  Impact of circulation on export production, dissolved organic matter, and dissolved oxygen in the ocean: Results from Phase II of the Ocean Carbon‐cycle Model Intercomparison Project (OCMIP‐2) , 2007 .

[36]  Olivier Aumont,et al.  The fate of pelagic CaCO 3 production in a high CO 2 ocean: a model study , 2007 .

[37]  S. Levitus,et al.  EOF analysis of upper ocean heat content, 1956–2003 , 2005 .

[38]  C. Jones,et al.  Development and evaluation of an Earth-System model - HadGEM2 , 2011 .

[39]  Stephanie Dutkiewicz,et al.  Interactions of the iron and phosphorus cycles: A three‐dimensional model study , 2005 .

[40]  Philippe Gaspar,et al.  A simple eddy kinetic energy model for simulations of the oceanic vertical mixing: Tests at Station Papa and long-term upper ocean study site , 1990 .

[41]  Andreas Oschlies,et al.  A model-based assessment of the TrOCA approach for estimating anthropogenic carbon in the ocean , 2010 .

[42]  W. Richard,et al.  TEMPERATURE AND PHYTOPLANKTON GROWTH IN THE SEA , 1972 .

[43]  Stephen Barker,et al.  Assessment of the spatial variability in particulate organic matter and mineral sinking fluxes in the ocean interior: Implications for the ballast hypothesis , 2012 .

[44]  Casper Labuschagne,et al.  Saturation of the Southern Ocean CO2 Sink Due to Recent Climate Change , 2007, Science.

[45]  U. Riebesell,et al.  Enhanced biological carbon consumption in a high CO2 ocean , 2006, Nature.

[46]  J. Huisman,et al.  Climate-driven changes in the ecological stoichiometry of aquatic ecosystems. , 2010 .

[47]  Julia C. Hargreaves,et al.  Assessing the potential long-term increase of oceanic fossil fuel CO 2 uptake due to CO 2 -calcification feedback , 2007 .

[48]  Keith Lindsay,et al.  Upper ocean ecosystem dynamics and iron cycling in a global three‐dimensional model , 2004 .

[49]  Scott C. Doney,et al.  Projected 21st century decrease in marine productivity: a multi-model analysis , 2009 .

[50]  John P. Dunne,et al.  A measured look at ocean chlorophyll trends , 2011, Nature.

[51]  C. L. De La Rocha,et al.  Accumulation of mineral ballast on organic aggregates , 2006 .

[52]  Gurvan Madec,et al.  Potential impact of climate change on marine export production , 2001 .

[53]  Toby Tyrrell,et al.  A modelling study of Emiliania huxleyi in the NE atlantic , 1996 .

[54]  E. Maier‐Reimer,et al.  Anthropogenic ocean acidification over the twenty-first century and its impact on calcifying organisms , 2005, Nature.

[55]  Thierry Penduff,et al.  Eddy-permitting ocean circulation hindcasts of past decades , 2007 .

[56]  A. Semtner A MODEL FOR THE THERMODYNAMIC GROWTH OF SEA ICE IN NUMERICAL INVESTIGATIONS OF CLIMATE , 1975 .

[57]  Nancy Knowlton,et al.  Climate change impacts on marine ecosystems. , 2012, Annual review of marine science.

[58]  Thomas R. Anderson,et al.  Plankton functional type modelling : running before we can walk? , 2005 .

[59]  Tyler Volk,et al.  Ocean Carbon Pumps: Analysis of Relative Strengths and Efficiencies in Ocean‐Driven Atmospheric CO2 Changes , 2013 .

[60]  Ulf Riebesell,et al.  Decreasing marine biogenic calcification: A negative feedback on rising atmospheric pCO2 , 2001 .

[61]  T. Stocker,et al.  An improved method for detecting anthropogenic CO2 in the oceans , 1996 .

[62]  Deborah K. Steinberg,et al.  Revisiting Carbon Flux Through the Ocean's Twilight Zone , 2006, Science.

[63]  G. Müller,et al.  The Scientific Basis , 1995 .

[64]  Andrew J. Watson,et al.  Ocean acidification due to increasing atmospheric carbon dioxide , 2005 .

[65]  David Archer,et al.  Association of sinking organic matter with various types of mineral ballast in the deep sea: Implications for the rain ratio , 2002 .

[66]  R. Betts,et al.  Acceleration of global warming due to carbon-cycle feedbacks in a coupled climate model , 2000, Nature.

[67]  M. Brandon,et al.  Transport and variability of the Antarctic Circumpolar Current in Drake Passage , 2003 .

[68]  Nicholas R. Bates,et al.  Pelagic functional group modeling: Progress, challenges and prospects , 2006 .

[69]  S. Wakeham,et al.  A new, mechanistic model for organic carbon fluxes in the ocean based on the quantitative association of POC with ballast minerals , 2001 .

[70]  E. Buitenhuis,et al.  University of Groningen Photosynthesis and Calcification by Emiliania huxleyi (Prymnesiophyceae) as a Function of Inorganic Carbon Species Buitenhuis, , 1999 .

[71]  Kenneth L. Denman,et al.  Preindustrial, historical, and fertilization simulations using a global ocean carbon model with new parameterizations of iron limitation, calcification, and N2 fixation , 2008 .

[72]  Edward A. Boyle,et al.  Decoupling of iron and phosphate in the global ocean , 2005 .

[73]  H. Hasumi,et al.  Evaluating effect of ballast mineral on deep‐ocean nutrient concentration by using an ocean general circulation model , 2008 .

[74]  Zhaomin Wang,et al.  Representation of the Antarctic Circumpolar Current in the CMIP5 climate models and future changes under warming scenarios , 2012 .

[75]  R. Feely,et al.  Ocean acidification: the other CO2 problem. , 2009, Annual review of marine science.

[76]  J. Lamarque,et al.  The HadGEM2-ES implementation of CMIP5 centennial simulations , 2011 .

[77]  T. R. Anderson,et al.  Medusa-1.0: a new intermediate complexity plankton ecosystem model for the global domain , 2010 .

[78]  K. Caldeira,et al.  Oceanography: Anthropogenic carbon and ocean pH , 2003, Nature.

[79]  P. Falkowski,et al.  Photosynthetic rates derived from satellite‐based chlorophyll concentration , 1997 .