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Changes in the Atlantic Sector of the Southern Ocean estimated from the CESM Last Millennium Ensemble

Published online by Cambridge University Press:  18 January 2019

Ilana Wainer Open the ORCID record for Ilana Wainer [Opens in a new window]  and
Peter R. Gent
Ilana Wainer*
Affiliation:
Oceanography Institute at the University of São Paulo, São Paulo-SP, 05508-120, Brazil
Peter R. Gent
Affiliation:
National Center for Atmospheric Research, Boulder, CO80307, USA
*
*wainer@usp.br
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Abstract

The changes in the Antarctic Circumpolar Current system associated with the Polar, sub-Antarctic and Subtropical Fronts in the Atlantic are examined in a ten-member ensemble using the Community Earth System Model. Results for the ensemble average mean show that the Polar Front at 25°W shifts to the south by 0.8° during 1970–2000 compared to its mean latitude over the period 1050–1950. This shift is significant because it is more than twice the standard deviation of the mean latitude time series during 1050–1950. The shift is caused by a slight southward displacement of the Antarctic Circumpolar Current, which in turn is caused by a southward shift in the latitude of the maximum zonal wind stress. The sub-Antarctic Front also shows a small southward shift after 1970, with a maximum latitudinal displacement of 0.2°. However, this shift is not significant compared to the standard deviation of the time series during 1050–1950. The Subtropical Front does not change its latitude during 1970–2000 compared to 1050–2000 because there is very little change in the wind-stress curl in the subtropics. Differences in temperature and salinity throughout the water column at 25°W reveal that during 1970–2000 there is freshening of Antarctic Intermediate Water, whereas the Circumpolar Deep Water becomes saltier.

Keywords

ACC systemclimate changeSouth AtlanticSouthern Hemispherewesterlies
Type
Physical Sciences
Information
Antarctic Science , Volume 31 , Issue 1 , February 2019 , pp. 37 - 51
Copyright
© Antarctic Science Ltd 2019 

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References

Berger, A. 1978. Long-term variations of daily insolation and Quaternary climatic changes. Journal of Atmospheric Science, 35, 23622367.Google Scholar
Boyer, T.P., Antonov, J.I., Baranova, O.K., Coleman, C., Garcia, H.E., Grodsky, A., et al . 2013. World Ocean Database 2013. Silver Spring, MD: NOAA Printing Office, 208 pp.Google Scholar
Danabasoglu, G., Bates, S.C., Briegleb, B.P., Jayne, S.R., Jochum, M., Large, W.G., et al. 2012. The CCSM4 ocean component. Journal of Climate, 25, 13611389.Google Scholar
Delworth, T., Broccoli, A.J., Rosati, A., Stouffer, R.J., Balaji, V., Beesley, J.A., et al. 2006. GFDL's CM2 global coupled climate models − part 1: formulation and simulation characteristics. Journal of Climate, 19, 10.1175/JCLI3629.1.Google Scholar
Dong, S., Sprintall, J. & Gille, S. 2006. Location of the Antarctic Polar Front from AMSR-E satellite sea surface temperature measurements. Journal of Physical Oceanography, 36, 20752089.Google Scholar
Downes, S.M., Budnick, A.S., Sarmiento, J.L. & Farneti, R. 2011. Impacts of wind stress on the Antarctic Circumpolar Current fronts and associated subduction. Geophysical Research Letters, 38, 10.1029/2011GL047668.Google Scholar
Fan, T., Deser, C. & Schneider, D.P. 2014. Recent Antarctic sea ice trends in the context of Southern Ocean surface climate variations since 1950. Geophysical Research Letters, 41, 24192426.Google Scholar
Farneti, R., Downes, S., Griffies, S.M., Marsland, S.J., Behrens, E. Bentsen, M., et al. 2015. An assessment of Antarctic Circumpolar Current and Southern Ocean meridional overturning circulation during 1958–2007 in a suite of interannual CORE-II simulations. Ocean Modelling, 93, 84120.Google Scholar
Freeman, N.M. & Lovenduski, N.S. 2016. Mapping the Antarctic Polar Front: weekly realizations from 2002 to 2014. Earth System Science Data, 8, 191198.Google Scholar
Fyfe, J.C., Saenko, O.A., Zickfeld, K. Eby, M. & Weaver, A.J. 2007. The role of poleward-intensifying winds on Southern Ocean warming. Journal of Climate, 20, 53915400.Google Scholar
Gao, C., Robock, A. & Ammann, C. 2008. Volcanic forcing of climate over the past 1500 years: an improved ice core-based index for climate models. Journal of Geophysical Research - Atmospheres, 113, 10.1029/2008JD010239.Google Scholar
Gent, P.R. 2016. Effects of Southern Hemisphere wind changes on the meridional overturning circulation in ocean models. Annual Review of Marine Science, 8, 7994.Google Scholar
Gent, P.R. & Danabasoglum, G. 2011. Response to increasing Southern Hemisphere winds in CCSM4. Journal of Climate, 24, 49924998.Google Scholar
Gent, P.R & McWilliams, J.C. 1990. Isopycnal mixing in ocean circulation models. Journal of Physical Oceanography, 20, 150155.Google Scholar
Gille, S. 2014. Meridional displacement of the Antarctic Circumpolar Current. Philosophical Transactions of the Royal Society, A372, 10.1098/rsta.2013.0273.Google Scholar
Graham, R.M., De Boer, A.M., Heywood, K.J., Chapman, M.R. & Stevens, D.P. 2012. Southern Ocean fronts: controlled by wind or topography? Journal of Geophysical Research - Oceans, 117, 114.Google Scholar
Huang, B., Banzon, V., Freeman, E., Lawrimore, J., Liu, W., Peterson, T., et al . 2015. Extended reconstructed sea surface temperature version (ERSST) v4. Part I: upgrades and intercomparisons. Journal of Climate, 28, 911930.Google Scholar
Kay, J.E., Deser, C., Phillips, A., Mai, A., Hannay, C., Strand, G., et al. 2015. The Community Earth System Model (CESM) large ensemble project: a community resource for studying climate change in the presence of internal climate variability. Bulletin of the American Meteorological Society, 96, 13331349.Google Scholar
Kim, Y.S. & Orsi, A.H. 2014. On the variability of Antarctic Circumpolar Current fronts inferred from 1992–2011 altimetry. Journal of Physical Oceanography, 44, 30543071.Google Scholar
Landrum, L., Otto-Bliesner, B., Wahl, E., Conley, A., Lawrence, P., Rosenbloom, N., et al . 2013. Last millennium climate and its variability in CCSM4. Journal of Climate, 26, 10851111.Google Scholar
McCartney, M.S. 1977. Sub-Antarctic mode water. In Angel, M.V ., ed. A voyage of discovery: George Deacon 70th anniversary volume. Oxford: Pergamon, 712 pp.Google Scholar
Meredith, M.P., Woodworth, P., Chereskin, T., Marshall, D., Allison, L., Bigg, G., et al . 2011. Sustained monitoring of the Southern Ocean at Drake Passage: past achievements and future priorities. Reviews of Geophysics, 49, 10.1029/2010RG000348.Google Scholar
Orsi, A.H., Whitworth, T. & Nowlin, W.D. 1995. On the meridional extent and fronts of the Antarctic Circumpolar Current. Deep-Sea Research I, 42, 641673.Google Scholar
Otto-Bliesner, B., Brady, E., Fasullo, J., Jahn, A., Landrum, L., Stevenson, S., et al . 2016. Climate variability and change since 850 CE: an ensemble approach with the Community Earth System Model. Bulletin of the American Meteorological Society, 97, 10.1175/BAMS-D-14-00233.1.Google Scholar
Polvani, L., Waugh, D., Correa, G. & Son, S. 2011. Stratospheric ozone depletion: the main driver of twentieth-century atmospheric circulation changes in the Southern Hemisphere. Journal of Climate, 24, 795812.Google Scholar
Rintoul, S.R., Hughes, C. & Olbers, D. 2001. The Antarctic Circumpolar System. In Siedler, G., Church, J. & Gould, J., eds. Ocean circulation and climate. New York: Academic Press, 715 pp.Google Scholar
Russell, J.L., Dixon, K.W., Gnanadesikan, A., Stouer, R.J. & Toggweiler, J.R. 2006. The Southern Hemisphere westerlies in a warming world: propping open the door to the deep ocean. Journal of Climate, 19, 63826390.Google Scholar
Sallée, J.B., Speer, K. & Morrow, R. 2008. Response of the Antarctic Circumpolar Current to atmospheric variability. Journal of Climate, 21, 30203039.Google Scholar
Santoso, A., & England, M.H. 2004. Antarctic Intermediate Water circulation and variability in a coupled climate model. Journal of Physical Oceanography, 34, 21602179.Google Scholar
Schmidt, G.A., Jungclaus, J.H., Ammann, C.M., Bard, E., Braconnot, P., Crowley, T.J., et al . 2012. Climate forcing reconstructions for use in PMIP simulations of the last millennium. Geoscience Model Development, 5, 185191.Google Scholar
Shao, A., Gille, S., Mecking, S. & Thompson., L. 2015. Properties of the sub-Antarctic Front and Polar Front from the skewness of sea level anomaly. Journal of Geophysical Research - Oceans, 120, 51795193.Google Scholar
Smith, T.M. & Reynolds, R.W. 2004. Improved extended reconstruction of SST (1854–1997). Journal of Climate, 17, 24662477.Google Scholar
Smythe-Wright, D., Chapman, P., Duncombe Rae, C., Shannon, L.V. & Boswell, S.M. 1998. Characteristics of the South Atlantic subtropical frontal zone between 15°W and 5°E. Deep Sea Research I, 45, 167192.Google Scholar
Sokolov, S., & Rintoul, S.R. 2009. Circumpolar structure and distribution of the Antarctic Circumpolar Current Fronts: 1. Mean circumpolar paths. Journal of Geophysical Research - Oceans, 114, 119.Google Scholar
Stramma, L. & England, M.H. 1999. On the water masses and mean circulation of the South Atlantic Ocean. Journal of Geophysical Research – Oceans, 104, 2086320883.Google Scholar
Talley, L.D., Pickard, G.L., Emery, W.J. & Swift, J.H. 2011. Descriptive physical oceanography: an introduction. London: Academic Press, 560 pp.Google Scholar
Toggweiler, J.R. 2009. Shifting westerlies. Science, 323, 14341435.Google Scholar
Wainer, I., Goes, M., Murphy, L.N. & Brady, E. 2012. Changes in the intermediate water mass formation rates in the global ocean for the Last Glacial Maximum, mid-Holocene and pre-industrial climates. Paleoceanography, 27, 10.1029/2012PA002290.Google Scholar
Whitworth, T. 1983. Monitoring the transport of the Antarctic Circumpolar Current at Drake Passage. Journal of Physical Oceanography, 13, 20452057.Google Scholar