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Evolution of upper layer temperature in the Bay of Biscay during the last 40 years

Published online by Cambridge University Press:  03 February 2010

Sylvain Michel
Affiliation:
Ifremer, département Dynamiques de l'Environnement Côtier, laboratoire de Physique Hydrodynamique et Sédimentaire, centre de Brest, BP 70, 29280 Plouzané, France
Frédéric Vandermeirsch
Affiliation:
Ifremer, département Dynamiques de l'Environnement Côtier, laboratoire de Physique Hydrodynamique et Sédimentaire, centre de Brest, BP 70, 29280 Plouzané, France
Pascal Lorance
Affiliation:
Ifremer, département Études et Modélisation pour l'Halieutique, BP 21105, 44311 Nantes Cedex, France
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Abstract

The temperature evolution over the past 40 years in the Bay of Biscay (North-East Atlantic) is investigated from an in situ data analysis, completed with a satellite SST (Sea Surface Temperature) analysis over the last 20 years. The in situ dataset is an interannual version of the BoByClim climatology, covering the Bay of Biscay area with a 10-km horizontal resolution and a 5-m vertical step. The satellite dataset is the European COastral Sea Operational Observing and Forcast System Program (ECOOP) daily analysis, covering the IBIROOS (Iberian-Biscay-Irish Sea) area with a 4-km resolution. The study area (43°N-50°N/12°W-1°W) extends over the intersection of the domains covered by these two analyses. In the 0–200 m layer of this domain, a heat budget has been computed from an ocean circulation model over the period 1965-2004. Heat is essentially imported from the west by the North Atlantic Drift, then exported southward and northward, or transferred downward into deeper layers. The annual average of air-sea flux is weak, with a zero isoline crossing the domain from the northwest to the southeast. Ocean and atmosphere, forming a coupled system, have comparable contributions and may both result in a heat sink or source. At the interannual scale, variability is mainly controlled by the air-sea flux, with a secondary contribution from oceanic transport. A strong warming of $\sim $ 0.2 °C/decade for the period 1965-2004 is apparent from the surface down to the 200-m depth. The decadal evolution is consistent with several analyses over the North Atlantic. Meanwhile, warming is approximately twice faster than in the whole basin. This trend is not steady, as a cooling period occurred until the early 1970's, and the temperature increase has been significantly stronger during the last 20 years ( $\sim $ 0.3 °C/decade between 0 and 100 m, from 1986 to 2005). The trend and the interannual variability are maximal over the northern part of the shelf. The typical duration of interannual anomalies is two years and their penetration depth is ~100 m, although they occasionally exceed 200 m. The interseasonal anomalies are also stronger within the mixed layer (root-mean-square, RMS = 0.6 °C at the surface) than below (RMS = 0.3 °C at 100 m). Their geographic distribution is radically different between the surface and the deep levels. A seasonal dependence of the warming rate is evident in the upper layer, as the temperature trend is stronger in summer than in winter (by a factor of 2 at the surface). Some of the potential implications for the ecosystem are discussed, particularly in terms of species distribution and dynamics of species exploited by fisheries.

Type
Research Article
Copyright
© EDP Sciences, IFREMER, IRD, 2009

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References

Barnier, B., et al., 2006, Impact of partial steps and momentum advection schemes in a global ocean circulation model at eddy permitting resolution. Ocean Dyn. 56, 543567. CrossRef
Benoit, H.P., Swain, D.P., 2008, Impacts of environmental change and direct and indirect harvesting effects on the dynamics of a marine fish community. Can. J. Fish. Aquat. Sci. 65, 20882104. CrossRef
Beaugrand, G., Reid, P.C., Ibañez, F., Lindlay, J.A., Edwards, M., 2002, Reorganization of North Atlantic marine copepod biodiversity and climate. Science 296, 16921694. CrossRef
Beaugrand, G., Brander, K.M., Lindley, J.A., Souissi, S., Reid, P.C., 2003, Plankton effect on cod recruitment in the North Sea. Nature 426, 661664. CrossRef
Blanchard, F., Vandermeirsch, F., 2005, Warming and exponential abundance increase of the subtropical fish Capros aper in the Bay of Biscay (1973-2002). C. R. Biol. 328, 505509. doi:10.1016/j.crvi.2004.12.006 CrossRef
Brander, K.M., 2007, Global fish production and climate change. Proc. Natl. Acad. Sci. USA 104, 1970919714. CrossRef
Brodeau L., Barnier B., Treguier A.M., Penduff T., 2007, Comparing sea surface atmospheric variables from ERA40 and CORE with a focus on global net heat flux. Flux News, newsletter of the WCRP workgroup on surface fluxes, 6-8 January 2007.
Curry, R., Mauritzen, C., 2005, Dilution of the northern North Atlantic Ocean in recent decades. Science 308, 17721774. CrossRef
Fabry, V.J., Seibel, B.A., Feely, R.A., Orr, J.C., 2008, Impacts of ocean acidification on marine fauna and ecosystem processes. ICES J. Mar. Sci. 65, 414432. CrossRef
Fontán, A., Valencia, V., Borja, A., Goikoetxea, N., 2008, Oceano-meteorological conditions and coupling in the southeastern Bay of Biscay, for the period 2001–2005: A comparison with the past two decades. J. Mar. Syst. 72, 167177. CrossRef
Friocourt, Y., Levier, B., Speich, S., Blanke,B., Drijfhout S.S., 2007, A regional numerical ocean model of the circulation in the Bay of Biscay. J. Geophys. Res. 112, C09008. CrossRef
Hermant M., Lobry J., Bonhommeau S., Poulard J.-C., Le Pape O., 2009, Impact of warming on abundance and occurrence of flatfish populations in the Bay of Biscay (France). J. Sea Res. 62.
Hsieh, C.H., Reiss, C.S., Hewitt, R.P., Sugihara, G., 2008, Spatial analysis shows that fishing enhances the climatic sensitivity of marine fishes. Can. J. Fish. Aquat. Sci. 65, 947961. CrossRef
Ivchenko V.O., Wells N.C., Aleynik D.L., 2006, Anomaly of heat content in the northern Atlantic in the last 7 years: Is the ocean warming or cooling? Geophys. Res. Lett. 33.
Knight J.R., Allan R.J., Folland C.K., Vellinga M., Mann M.E., 2005, A signature of persistent natural thermohaline circulation cycles in observed climate. Geophys. Res. Lett. 32.
Koutsikopoulos, C., Beillois, P., Leroy, C., Taillefer, F., 1998, Temporal trends and spatial structures of the sea surface temperature in the Bay of Biscay. Oceanol. Acta 21, 335344. CrossRef
Large W.G., 2007, CORE forcing for coupled ocean and sea-ice models. Flux News, newsletter of the WCRP workgroup on surface fluxes, 2-3 January 2007.
Le Pape, O., Chauvet, F., Désaunay, Y., Guérault, D., 2003, Relationship between interannual variations of the river plume and the extent of nursery grounds for the common sole (Solea solea L.) in Vilaine Bay. Effects on recruitment variability. J. Sea Res. 50, 177185. CrossRef
Levitus, S., Antonov, J., Boyer, T., 2005, Warming of the World Ocean: 1955-2003. Geophys. Res. Lett. 32, L02604.
Lozier, M.S., Leadbetter, S., Williams, R.G., Roussenov, V., Reed, M.S.C., Moore, N.J., 2008, The spatial pattern and mechanisms of heat-content change in the North Atlantic. Science 319, 800803. CrossRef
Michel, S., Treguier, A.M., Vandermeirsch, F., 2009, Temperature variability in the Bay of Biscay during the past 40 years, from an in situ analysis and a 3D global simulation. Cont. Shelf Res. 29, 10701087. CrossRef
Miller, W.D., Harding, L.W Jr., 2007, Climate forcing of the spring bloom in Chesapeake Bay. Mar. Ecol. Prog. Ser. 331, 1122. CrossRef
Persohn, C., Lorance, P., Trenkel, V.M., 2009, Habitat preferences of selected demersal fish species in the Bay of Biscay and Celtic Sea, North-East Atlantic. Fish. Oceanogr. 18, 268285. CrossRef
Planque, B., Beillois, P., Jégou, A.M., Lazure, P., Petitgas, P., Puillat, I., 2003, Large-scale hydroclimatic variability in the Bay of Biscay: the 1990's in the context of interdecadal changes. ICES Mar. Sci. Symp. 219, 6170.
Planque, B., Bellier, E., Lazure, P., 2007, Modelling potential spawning habitat of sardine (Sardina pilchardus) and anchovy (Engraulis encrasicolus) in the Bay of Biscay. Fish. Oceanogr. 16, 1630. CrossRef
Planque, B., Buffaz, L., 2008, Quantile regression models for fish recruitment environment relationships: four case studies. Mar. Ecol.-Prog. Ser. 357, 213223. CrossRef
Poulard, J.C., Blanchard, F., 2005, The impact of climate change on the fish community structure of the eastern continental shelf of the Bay of Biscay. ICES J. Mar. Sci. 62, 14361443. CrossRef
Quéro, J.C., Du Buit, M.H., Vayne, J.J., 1998, Les observations de poissons tropicaux et le réchauffement des eaux dans l' Atlantique européen. Oceanol. Acta 21, 345351. CrossRef
Rijnsdorp, A., Peck, M.A., Engelhard, G.H., Möllmann, C., Pinnegar, J.K., 2009, Resolving the effect of climate change on fish populations. ICES J. Mar. Sci. 66, 15701583. CrossRef
Saulquin B., Gohin F., 2009, Mean seasonal cycle and evolution of the sea surface temperature from satellite and in situ data in the English Channel for the period 1985-2006. Int. J. Remote Sensing.
Stenseth, N.C., Mysterud, A., Ottersen, G., Hurrell, J.W., Chan, K-S., Lima, M., 2002, Ecological effects of climate fluctuations. Science 297, 12921296. CrossRef
Stige, L.C., Ottersen, G., Brander, K., Chan, K.-S., Stenseth, N.C., 2006, Cod and climate: effect of the North Atlantic Oscillation on recruitment in the North Atlantic. Mar Ecol. Prog. Ser. 325, 227241. CrossRef
Vandermeirsch F., Charraudeau M., Bonnat A., Fichaut M., Maillard C., Gaillard F., Autret E., 2008, Bay of Biscay's temperature and salinity climatology. XI International Symposium on Oceanography of the Bay of Biscay, 1-4 April 2008, San Sebastian.