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Changes in the Subduction of Southern Ocean Water Masses at the End of the Twenty-First Century in Eight IPCC Models (2010)

Downes, Stephanie M. ; Bindoff, Nathaniel L. ; Rintoul, Stephen R.

American Meteorological Society

In: Journal of Climate. 2010; 23(24): 6526-6541. Published 2010 Dec 15. doi: 10.1175/2010jcli3620.1.

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Publication Date: 2010-12-15

Description: A multimodel comparison method is used to assess the sensitivity of Subantarctic Mode Water (SAMW) and Antarctic Intermediate Water (AAIW) formation to climate change. For the Intergovernmental Panel on Climate Change A2 emissions scenario (where atmospheric CO2 is 860 ppm at 2100), the models show cooling and freshening on density surfaces less than about 27.4 kg m−3, a pattern that has been observed in the late twentieth century. SAMW (defined by the low potential vorticity layer) and AAIW (defined by the salinity minimum layer) warm and freshen as they shift to lighter density classes. Heat and freshwater fluxes at the ocean surface dominate the projected buoyancy gain at outcrop regions of SAMW and AAIW, whereas the net increase in the Ekman flux of heat and freshwater contributes to a lesser extent. This buoyancy gain, combined with shoaling of the winter mixed layer, reduces the volume of SAMW subducted into the ocean interior by a mean of 8 Sv (12%), and the subduction of AAIW decreases by a mean of 14 Sv (23%; 1 Sv ≡ 106 m3 s−1). Decreases in the projected subduction of the key Southern Ocean upper-water masses imply a slow down in the Southern Ocean circulation in the future, driven by surface warming and freshening. A reduction in the subduction of intermediate waters implies a likely future decrease in the capacity of the Southern Ocean to sequester CO2.

Print ISSN: 0894-8755

Electronic ISSN: 1520-0442

Topics: Geography , Geosciences , Physics

Published by American Meteorological Society

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The GFDL CM3 Coupled Climate Model: Characteristics of the Ocean and Sea Ice Simulations (2011)

Griffies, Stephen M. ; Winton, Michael ; Donner, Leo J. ; [et al.]

American Meteorological Society

In: Journal of Climate. 2011; 24(13): 3520-3544. Published 2011 Jul 01. doi: 10.1175/2011jcli3964.1.

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Publication Date: 2011-07-01

Description: This paper documents time mean simulation characteristics from the ocean and sea ice components in a new coupled climate model developed at the NOAA Geophysical Fluid Dynamics Laboratory (GFDL). The GFDL Climate Model version 3 (CM3) is formulated with effectively the same ocean and sea ice components as the earlier CM2.1 yet with extensive developments made to the atmosphere and land model components. Both CM2.1 and CM3 show stable mean climate indices, such as large-scale circulation and sea surface temperatures (SSTs). There are notable improvements in the CM3 climate simulation relative to CM2.1, including a modified SST bias pattern and reduced biases in the Arctic sea ice cover. The authors anticipate SST differences between CM2.1 and CM3 in lower latitudes through analysis of the atmospheric fluxes at the ocean surface in corresponding Atmospheric Model Intercomparison Project (AMIP) simulations. In contrast, SST changes in the high latitudes are dominated by ocean and sea ice effects absent in AMIP simulations. The ocean interior simulation in CM3 is generally warmer than in CM2.1, which adversely impacts the interior biases.

Print ISSN: 0894-8755

Electronic ISSN: 1520-0442

Topics: Geography , Geosciences , Physics

Published by American Meteorological Society

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Southern Ocean Circulation and Eddy Compensation in CMIP5 Models (2013)

Downes, Stephanie M. ; Hogg, Andrew McC.

American Meteorological Society

In: Journal of Climate. 2013; 26(18): 7198-7220. Published 2013 Sep 09. doi: 10.1175/jcli-d-12-00504.1.

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Publication Date: 2013-09-09

Description: Thirteen state-of-the-art climate models from phase 5 of the Coupled Model Intercomparison Project (CMIP5) are used to evaluate the response of the Antarctic Circumpolar Current (ACC) transport and Southern Ocean meridional overturning circulation to surface wind stress and buoyancy changes. Understanding how these flows—fundamental players in the global distribution of heat, gases, and nutrients—respond to climate change is currently a widely debated issue among oceanographers. Here, the authors analyze the circulation responses of these coarse-resolution coupled models to surface fluxes. Under a future CMIP5 climate pathway where the equivalent atmospheric CO2 reaches 1370 ppm by 2100, the models robustly project reduced Southern Ocean density in the upper 2000 m accompanied by strengthened stratification. Despite an overall increase in overlying wind stress (~20%), the projected ACC transports lie within ±15% of their historical state, and no significant relationship with changes in the magnitude or position of the wind stress is identified. The models indicate that a weakening of ACC transport at the end of the twenty-first century is correlated with a strong increase in the surface heat and freshwater fluxes in the ACC region. In contrast, the surface heat gain across the ACC region and the wind-driven surface transports are significantly correlated with an increased upper and decreased lower Eulerian-mean meridional overturning circulation. The change in the eddy-induced overturning in both the depth and density spaces is quantified, and it is found that the CMIP5 models project partial eddy compensation of the upper and lower overturning cells.

Print ISSN: 0894-8755

Electronic ISSN: 1520-0442

Topics: Geography , Geosciences , Physics

Published by American Meteorological Society

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Water Mass Exchange in the Southern Ocean in Coupled Climate Models (2011)

Downes, Stephanie M. ; Gnanadesikan, Anand ; Griffies, Stephen M. ; [et al.]

American Meteorological Society

In: Journal of Physical Oceanography. 2011; 41(9): 1756-1771. Published 2011 Sep 01. doi: 10.1175/2011jpo4586.1.

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Publication Date: 2011-09-01

Description: The authors estimate water mass transformation rates resulting from surface buoyancy fluxes and interior diapycnal fluxes in the region south of 30°S in the Estimating the Circulation and Climate of the Ocean (ECCO) model-based state estimation and three free-running coupled climate models. The meridional transport of deep and intermediate waters across 30°S agrees well between models and observationally based estimates in the Atlantic Ocean but not in the Indian and Pacific, where the model-based estimates are much smaller. Associated with this, in the models about half the southward-flowing deep water is converted into lighter waters and half is converted to denser bottom waters, whereas the observationally based estimates convert most of the inflowing deep water to bottom waters. In the models, both Antarctic Intermediate Water (AAIW) and Antarctic Bottom Water (AABW) are formed primarily via an interior diapycnal transformation rather than being transformed at the surface via heat or freshwater fluxes. Given the small vertical diffusivity specified in the models in this region, the authors conclude that other processes such as cabbeling and thermobaricity must be playing an important role in water mass transformation. Finally, in the models, the largest contribution of the surface buoyancy fluxes in the Southern Ocean is to convert Upper Circumpolar Deep Water (UCDW) and AAIW into lighter Subantarctic Mode Water (SAMW).

Print ISSN: 0022-3670

Electronic ISSN: 1520-0485

Topics: Geosciences , Physics

Published by American Meteorological Society

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Role of the Seasonal Cycle in the Subduction Rates of Upper–Southern Ocean Waters (2013)

Kwon, Eun Young ; Downes, Stephanie M. ; Sarmiento, Jorge L. ; [et al.]

American Meteorological Society

In: Journal of Physical Oceanography. 2013; 43(6): 1096-1113. Published 2013 Jun 01. doi: 10.1175/jpo-d-12-060.1.

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Publication Date: 2013-06-01

Description: A kinematic approach is used to diagnose the subduction rates of upper–Southern Ocean waters across seasonally migrating density outcrops at the base of the mixed layer. From an Eulerian viewpoint, the term representing the temporal change in the mixed layer depth (which is labeled as the temporal induction in this study; i.e., Stemp = ∂h/∂t where h is the mixed layer thickness, and t is time) vanishes over several annual cycles. Following seasonally migrating density outcrops, however, the temporal induction is attributed partly to the temporal change in the mixed layer thickness averaged over a density outcrop following its seasonally varying position and partly to the lateral movement of the outcrop position intersecting the sloping mixed layer base. Neither the temporal induction following an outcrop nor its integral over the outcrop area vanishes over several annual cycles. Instead, the seasonal eddy subduction, which arises primarily because of the subannual correlations between the seasonal cycles of the mixed layer depth and the outcrop area, explains the key mechanism by which mode waters are transferred from the mixed layer to the underlying pycnocline. The time-mean exchange rate of waters across the base of the mixed layer is substantially different from the exchange rate of waters across the fixed winter mixed layer base in mode water density classes. Nearly 40% of the newly formed Southern Ocean mode waters appear to be diapycnally transformed within the seasonal pycnocline before either being subducted into the main pycnocline or entrained back to the mixed layer through lighter density classes.

Print ISSN: 0022-3670

Electronic ISSN: 1520-0485

Topics: Geosciences , Physics

Published by American Meteorological Society

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Tracing Southwest Pacific Bottom Water Using Potential Vorticity and Helium-3 (2012)

Downes, Stephanie M. ; Key, Robert M. ; Orsi, Alejandro H. ; [et al.]

American Meteorological Society

In: Journal of Physical Oceanography. 2012; 42(12): 2153-2168. Published 2012 Dec 01. doi: 10.1175/jpo-d-12-019.1.

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Publication Date: 2012-12-01

Description: This study uses potential vorticity and other tracers to identify the pathways of the densest form of Circumpolar Deep Water in the South Pacific, termed “Southwest Pacific Bottom Water” (SPBW), along the 28.2 kg m−3 surface. This study focuses on the potential vorticity signals associated with three major dynamical processes occurring in the vicinity of the Pacific–Antarctic Ridge: 1) the strong flow of the Antarctic Circumpolar Current (ACC), 2) lateral eddy stirring, and 3) heat and stratification changes in bottom waters induced by hydrothermal vents. These processes result in southward and downstream advection of low potential vorticity along rising isopycnal surfaces. Using δ3He released from the hydrothermal vents, the influence of volcanic activity on the SPBW may be traced across the South Pacific along the path of the ACC to Drake Passage. SPBW also flows within the southern limb of the Ross Gyre, reaching the Antarctic Slope in places and contributes via entrainment to the formation of Antarctic Bottom Water. Finally, it is shown that the magnitude and location of the potential vorticity signals associated with SPBW have endured over at least the last two decades, and that they are unique to the South Pacific sector.

Print ISSN: 0022-3670

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Topics: Geosciences , Physics

Published by American Meteorological Society

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