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High-frequency observations of pH under Antarctic sea ice in the southern Ross Sea

Published online by Cambridge University Press:  01 September 2011

Paul G. Matson ,
Todd R. Martz  and
Gretchen E. Hofmann
Paul G. Matson*
Affiliation:
Department of Ecology, Evolution, and Marine Biology, University of California, Santa Barbara, CA 93106-9620, USA
Todd R. Martz
Affiliation:
Scripps Institution of Oceanography, University of California, San Diego, CA 92093, USA
Gretchen E. Hofmann
Affiliation:
Department of Ecology, Evolution, and Marine Biology, University of California, Santa Barbara, CA 93106-9620, USA
*
[email protected]
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Abstract

Although predictions suggest that ocean acidification will significantly impact polar oceans within 20–30 years, there is limited information regarding present-day pH dynamics of the Southern Ocean. Here, we present novel high-frequency observations of pH collected during spring of 2010 using SeaFET pH sensors at three locations under fast sea ice in the southern Ross Sea. During these deployments in McMurdo Sound, baseline pH ranged between 8.019–8.045, with low to moderate overall variation (0.043–0.114 units) on the scale of hours to days. The variation was predominantly in the direction of increased pH relative to baseline observations. Estimates of aragonite saturation state (ΩAr) were > 1 with no observations of subsaturation. Time series records such as these are significant to the Antarctic science community; this information can be leveraged towards framing more environmentally relevant laboratory experiments aimed at assessing the vulnerability of Antarctic species to ocean acidification. In addition, increased spatial and temporal coverage of pH datasets may reveal ecologically significant patterns. Specifically, whether such variation in natural ocean pH dynamics may drive local adaptation to pH variation or provide refugia for populations of marine calcifiers in a future, acidifying ocean.

Keywords

AntarcticaMcMurdo Soundocean acidificationSeaFET sensor
Type
Physical Sciences
Information
Antarctic Science , Volume 23 , Issue 6 , 22 November 2011 , pp. 607 - 613
Copyright
Copyright © Antarctic Science Ltd 2011

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References

Barry, J.P. 1988. Hydrographic patterns in McMurdo Sound, Antarctica and their relationship to local benthic communities. Polar Biology, 8, 377391.Google Scholar
Barry, J.P.Dayton, P.K. 1988. Current patterns in McMurdo Sound, Antarctica and their relationship to local biotic communities. Polar Biology, 8, 367376.CrossRefGoogle Scholar
Comeau, S., Jeffree, R., Teyssié, J.L.Gattuso, J.P. 2010. Response of the Arctic pteropod Limacina helicina to projected future environmental conditions. PLoS One, 5, e11362.Google Scholar
Cummings, V., Hewitt, J., van Rooyan, A., Currie, K., Beard, S., Thrush, S., Norkko, J., Barr, N., Heath, P., Halliday, N.J., Sedcold, R., Gomez, A., McGraw, C.Metcalf, V. 2011. Ocean acidification at high latitudes: potential effects on functioning of the Antarctic bivalve Laternula elliptica. PLoS One, 6, e16069.Google Scholar
Dickson, A.G.Millero, F.J. 1987. A comparison of the equilibrium-constants for the dissociation of carbonic acid in seawater media. Deep-Sea Research, 34, 17331743.Google Scholar
Dickson, A.G., Sabine, C.L.Christian, J.R. 2007. Guide to best practices for ocean CO2 measurements. PICES Special Publication, 3, 191 pp.Google Scholar
Ericson, J.A., Lamare, M.D., Morley, S.A.Barker, M.F. 2010. The response of two ecologically important Antarctic invertebrates (Sterechinus neumayeri and Parborlasia corrugatus) to reduced seawater pH: effects on fertilization and embryonic development. Marine Biology, 157, 26892702.CrossRefGoogle Scholar
Fabry, V.J., McClintock, J.B., Mathis, J.T.Grebmeier, J.M. 2009. Ocean acidification at high latitudes: the bellweather. Oceanography, 22, 160171.CrossRefGoogle Scholar
Fangue, N.A., O'Donnell, M.J., Sewell, M.A., Matson, P.G., MacPherson, A.C.Hofman, G.E. 2010. A laboratory-based experimental system for the study of ocean acidification effects on marine invertebrate larvae. Limnology and Oceanography - Methods, 8, 441452.Google Scholar
Feely, R.A., Sabine, C.L., Hernandez-Ayon, J.M., Ianson, D.Hales, B. 2008. Evidence for upwelling of corrosive “acidified” water onto the continental shelf. Science, 320, 14901492.Google Scholar
Helmuth, B., Harley, C.D.G., Halpin, P.M., O'Donnell, M., Hofman, G.E.Blanchette, C.A. 2002. Climate change and latitudinal patterns of intertidal thermal stress. Science, 298, 10151017.CrossRefGoogle ScholarPubMed
Helmuth, B., Broitman, B.R., Yamane, L., Gilman, S.E., Mach, K., Mislan, K.A.S.Denny, M.W. 2010. Organismal climatology: analysing environmental variability at scale relevant to physiological stress. Journal of Experimental Biology, 213, 9951003.CrossRefGoogle Scholar
Hofmann, G.E., Barry, J.P., Edmunds, P.J., Gates, R.D., Hutchins, D.A., Klinger, T.Sewell, M.A. 2010. The effect of ocean acidification on calcifying organisms in marine ecosystems: an organism-to-ecosystem perspective. Annual Review of Ecology, Evolution, and Systematics, 41, 127147.Google Scholar
Kawaguchi, S., Kurihara, H., King, R., Hale, L., Berli, T., Robinson, J.P., Ishida, A., Wakita, M., Virtue, P., Nicol, S.Ishimatsu, A. 2011. Will krill fare well under Southern Ocean acidification? Biology Letters, 7, 288291.CrossRefGoogle ScholarPubMed
Kuo, E.S.L.Sanford, E. 2009. Geographic variation in the upper thermal limits of an intertidal snail: implications for climate envelope models. Marine Ecology Progress Series, 388, 137146.Google Scholar
Lebrato, M., Iglesias-Rodriguez, D., Feely, R.A., Greeley, D., Jones, D., Suarez-Bosche, N., Lampit, R., Cartes, J., Green, D.Alker, B. 2010. Global contribution of echinoderms to the marine carbon cycle: CaCO3 budget and benthic compartments. Ecological Monographs, 80, 441467.Google Scholar
Leichter, J.J., Helmuth, B.Fisher, A.M. 2006. Variation beneath the surface: quantifying complex thermal environments on coral reefs in the Caribbean, Bahamas, and Florida. Journal of Marine Science, 64, 563588.Google Scholar
Lewis, E.L.Perkin, R.G. 1985. The winter oceanography of McMurdo Sound, Antarctica. Antarctic Research Series, 43, 145166.Google Scholar
Littlepage, J.L. 1965. Oceanographic investigations in McMurdo Sound, Antarctica. Antarctic Research Series, 5, 137.Google Scholar
Martz, T.R., Connery, J.G.Johnson, K.S. 2010. Testing the Honeywell Durafet® for seawater pH applications. Limnology and Oceanography - Methods, 8, 172184.Google Scholar
McClintock, J., Ducklow, H.Fraser, W. 2008. Ecological responses to climate change on the Antarctic Peninsula. American Scientist, 96, 302310.Google Scholar
McClintock, J.B., Angus, R.A., McDonald, M.R., Amsler, C.D., Catledge, S.A.Vohra, Y.K. 2009. Rapid dissolution of shells of weakly calcified Antarctic benthic macroorganisms indicated high vulnerability to ocean acidification. Antarctic Science, 21, 449456.CrossRefGoogle Scholar
McMinn, A., Ryan, K.G., Ralph, P.J.Pankowski, A. 2007. Spring sea ice photosynthesis, primary productivity, and biomass distribution in eastern Antarctica, 2002–2004. Marine Biology, 151, 985995.Google Scholar
McMinn, A., Martin, A.Ryan, K. 2010. Phytoplankton and sea ice algal biomass and physiology during the transition between winter and spring (McMurdo Sound, Antarctica). Polar Biology, 33, 15471556.Google Scholar
McNeil, B.I.Matear, R.J. 2008. Southern Ocean acidification: a tipping point at 450-ppm atmospheric CO2. Proceedings of the National Academy of Sciences of the United States of America, 105, 18 86018 864.Google Scholar
McNeil, B.I., Sweeney, C.Gibson, J.A.E. 2011. Natural seasonal variability of aragonite saturation state within two Antarctic coastal ocean sites. Antarctic Science, 10.1017/S0954102011000204.CrossRefGoogle Scholar
McNeil, B., Tagliabue, A.Sweeney, C. 2010. A multidecadal delay in the onset of corrosive ‘acidified’ waters in the Ross Sea of Antarctica due to strong air-sea CO2 disequilibrium. Geophysical Research Letters, 37, 10.1029/2010GL044597.CrossRefGoogle Scholar
Mehrbach, C., Culberson, C.H., Hawley, J.E.Pytkowicz, R.M. 1973. Measurement of the apparent dissociation constants of carbonic acid in seawater at an atmospheric pressure. Limnology and Oceanography, 18, 897907.CrossRefGoogle Scholar
O'Donnell, M.J., Todgham, A.E., Sewell, M.A., Hammond, L.M., Ruggiero, K., Fangue, N.A., Zippay, M.L.Hofmann, G.E. 2010. Ocean acidification alters skeletogenesis and gene expression in larval sea urchins. Marine Ecology Progress Series, 398, 157171.CrossRefGoogle Scholar
Orr, J.C., Fabry, V.J., Aumont, O. et al. 2005. Anthropogenic ocean acidification over the twenty-first century and its impact on calcifying organisms. Nature, 437, 681686.Google Scholar
Peck, L.S., Morley, S.A.Clark, M.S. 2010. Poor acclimation capacities in Antarctic marine ectotherms. Marine Biology, 157, 20512059.CrossRefGoogle Scholar
Pierrot, D., Lewis, E.Wallace, D.W.R. 2006. MS Excel program developed for CO2 system calculations. ORNL/CDIAC-105a. Oak Ridge, TN: Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory, US Department of Energy.Google Scholar
Sanford, E.Kelly, M.W. 2011. Local adaptation in marine invertebrates. Annual Review of Marine Science, 3, 509535.Google Scholar
Sewell, M.A.Hofmann, G.E. 2011. Antarctic echinoids and climate change: a major impact on brooding forms. Global Change Biology, 17, 734744.CrossRefGoogle Scholar
Somero, G.N. 2010. The physiology of climate change: how potentials for acclimatization and genetic adaptation will determine ‘winners’ and ‘losers’. Journal of Experimental Biology, 213, 912920.CrossRefGoogle ScholarPubMed
Steinacher, M., Joos, F., Frölicher, T.L., Plattner, G.-K.Doney, S.C. 2009. Imminent ocean acidification in the Arctic projected with the NCAR global coupled carbon cycle-climate model. Biogeosciences, 6, 515533.Google Scholar
Turley, C., Eby, M., Ridgwell, A.J., Schmidt, D.N., Findlay, H.S., Brownlee, C., Riebesell, U., Fabry, V.J., Feely, R.S.Gattuso, J.-P. 2010. The societal challenge of ocean acidification. Marine Pollution Bulletin, 60, 787792.CrossRefGoogle ScholarPubMed
Yu, P.C., Matson, P.G., Martz, T.R.Hofmann, G.E. 2011. The ocean acidification seascape and its relationship to the performance of calcifying marine invertebrates: laboratory experiments on the development of urchin larvae framed by environmentally-relevant pCO2/pH. Journal of Experimental Marine Biology and Ecology, 400, 288295.CrossRefGoogle Scholar