The Southern Ocean carbon cycle response to future climate change

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This page is part of the topic Antarctic climate and environment change over the next 100 years

Background

5.21 Observed CO2 emissions over the last 25 years as compared with the different IPCC emission scenarios (Raupach et al., 2007[1]) (Copyright (2007) National Academy of Sciences, U.S.A).

Atmospheric CO2 emissions continue to increase at unprecedented rates. Already emissions have equalled or exceeded the previous worst-case scenarios for the IPCC (Raupach et al., 2007[1]; Figure 5.21). Currently it is estimated that about 30% of the CO2 emitted annually is taken up by the ocean (Sabine et al., 2004[2]). The Southern Ocean plays a critical role in taking up this CO2, with more than 40% of the annual mean uptake of atmospheric CO2 being taken up in the region south of 40°S (Takahashi et al., 2009[3]). Clearly then the way in which the Southern Ocean responds to climate change will directly impact global atmospheric CO2 levels and hence the rate of the earth’s warming. Hence, determining the role of the Southern Ocean in CO2 exchange must be a priority if we are to formulate effective global policies for stabilizing atmospheric CO2 levels.

Future Southern Ocean carbon response

Response to increased winds

As the Southern Ocean becomes windier in response to global warming there will be an associated increase in the upwelling of carbon-rich water from the deep ocean. As this upwelled carbon reaches the surface it will increase the CO2 content of surface water, reducing the pCO2 gradient between the atmosphere and the ocean, and hence the uptake of CO2 by the ocean from the atmosphere (Zickfeld et al., 2007[4]). At the same time atmospheric CO2 concentrations will continue to rise in response to human activities. Eventually, as the atmospheric concentration of CO2 exceeds the maximum deep-water pCO2 value, estimated to be 430 microatmospheres (μatm) (McNeil et al., 2007[5]), the Southern Ocean CO2 sink will then change from a saturated CO2 sink (Le Quéré et al., 2007[6]) to a strengthening CO2 sink. Model simulations suggest that this change will take place in the period 2020-2030 (under the IPCC A2 emission scenario) (Matear and Lenton, 2008[7]; Zickfeld et al., 2008[8]).

Response to ocean warming

5.22a Schematic of how global warming is expected to impact on dissolved inorganic carbon (DIC) in the ocean and hence air-sea carbon fluxes of CO2: sea surface warming decreases CO2 solubility (solid horizontal arrow) and drives outgassing (Large open arrow).

As the Southern Ocean becomes warmer, its ability to store CO2 through solubility changes is affected. Freshening associated with the warming will lead to a stratification of the upper ocean that will affect ocean carbon uptake through biogeochemical and physical changes. Warming will reduce the solubility of CO2 in seawater, so reducing the ocean’s ability to take up and store CO2 (Figure 5.22a). A warming of 1% decreases oceanic pCO2 by 4.23% (Takahashi et al., 1993[9]). The result of these solubility changes will be to reduce the pCO2 gradient between the atmosphere and the ocean, reducing the efficiency of ocean CO2 uptake. Various studies of future CO2 uptake suggest that the solubility effect will be significant (Matear and Hirst, 1999[10]; Plattner et al., 2001[11]; Sarmiento et al., 1998[12]), although its magnitude remains poor quantified.

5.22b Schematic of how global warming is expected to impact on dissolved inorganic carbon (DIC) in the ocean and hence air-sea carbon fluxes of CO2: increased stratification impacts CO2 through biological production; there is both enhanced biological production in response to warming and light supply, and reduction associated with reduced nutrient supply. The net effect is predicted to be an increase in CO2 uptake (large downward open arrow).

The Southern Ocean is a high nutrient low chlorophyll (HNLC) region rich in the macronutrients (nitrogen, phosphate and silicate) needed by phytoplankton to grow, but poor in phytoplankton, most likely due to a lack of micronutrients, in particular iron. It also suffers from the low levels of light at high latitude, which may inhibit productivity. As the upper ocean warms, freshens and stratifies, conditions will favour an increase in productivity. That in turn will use up CO2 in surface waters, which will increase the ocean – atmosphere pCO2 gradient, thereby encouraging more uptake of CO2 by the ocean from the atmosphere (Figure 5.22b). Increasing stratification of the surface ocean will also tend to limit the supply of nutrients from below, hence limiting productivity and increasing the uptake of CO2. The amount of nutrients available in the stratified surface waters, hence productivity and CO2 uptake, will also depend on the efficiency with which organic matter is exported out of the mixed layer by sinking (Figure 5.22b).

5.23 Primary Productivity (PP) changes PgC/degree calculated for the period averaged 2040-2060 using six different coupled climate carbon models (Sarmiento et al., 2004b[13]). PP changes were calculated using Behrenfield and Falkowski (1997[14]), and changes were assessed against control simulations that excluded global warming.

Bopp et al. (2001[15]) explored the relationship between the different competing processes in a coupled climate carbon model and showed that because the Southern Ocean was nutrient-limited, the largest effect was from stratification, which increased the interaction between light and nutrients and led to a longer and more efficient growing season with a 30% increase in marine productivity and export production. Consistent with this, Sarmiento et al. (2004b[13]) found that six different coupled climate carbon models showed increased primary production in the Southern Ocean between now and 2060 (Figure 5.23). The magnitude of the response was highly correlated with the strength of stratification, which in turn was related to changes in sea ice extent forced by continued global warming.

In addition to inducing biogeochemical changes, increased ocean stratification may also reduce uptake of CO2 from the atmosphere through Southern Ocean density changes. Mignone et al. (2006[16]) showed that the depth of the pycnocline is highly correlated with CO2 uptake. As a result it is predicted that as stratification increases the pycnocline will shallow, so further reducing CO2 uptake (Sarmiento et al., 1998[12]).

Response to increased CO2 uptake

5.24 Surface values of the Revelle factor computed with the IPSL Coupled Climate Carbon Model forced by the A2 scenario and for the recent past and future (1990-1999 and 2090-2099) (Friedlingstein et al, 2006[17]; Reprinted by permission from Macmillan Publishers Ltd: Nature doi:10.1038/nature04095, copyright (2005))

The uptake of CO2 by the Southern Ocean alters ocean carbonate chemistry, causing both a reduction in ocean pH (i.e. acidification) and a reduction in the ocean’s ability to take up and store CO2 through an increase in the Revelle Factor. The Revelle factor (Revelle and Suess, 1957[18]), or buffer capacity, describes by how much the concentration of CO2 in the ocean will change for a given increase in the partial pressure of CO2 (pCO2). The higher the Revelle (or buffer) Factor, the less able the ocean is to take up atmospheric CO2. As shown in Figure 5.24, the Revelle factor in the Southern Ocean lies between 10 and 15. In the next 100 years it is predicted to increase to 17 or more, which will reduce the efficiency of the ocean to take up atmospheric CO2.

5.25 Predicted aragonite saturation state of the surface ocean in the year 2100 (Orr et al., 2005[19]). The dashed line represents the saturation horizon and shows that much of the Southern Ocean (<50ºS) is expected to be under-saturated with respect to aragonite by 2100.

As the CO2 levels in the ocean increase, the associated changes in ocean carbonate chemistry will lower the pH. Currently the upper ocean is supersaturated with respect to aragonite (used by important grazers like pteropods), and calcite (used by coccolithophores). As the ocean becomes more acidic (lower pH), the saturation states of both aragonite and calcite will be reduced until they drop below 1, when they pass through the saturation horizon - the point where the saturation state changes from super- to under-saturated. When the waters become under-saturated with respect to either aragonite or calcite it will no longer be possible for marine organisms to use these compounds to build calcium carbonate shells (Feely et al., 2004[20]). Orr et al. (2005[19]) used a suite of ocean models to show that by 2100 the saturation horizon will have shallowed significantly, the pH having dropped by an additional 0.3, and hence much of the Southern Ocean will be under-saturated with respect to aragonite (Figure 5.25). This acidification is expected to bring about a shift in marine ecosystems (Feely et al., 2004[20]), and potentially a reduction in export production (Klaas and Archer, 2002[21]), although it has been suggested that this effect may be offset by increased CO2 uptake causing an increase in alkalinity (Heinze, 2004[22]).

While mean long-term changes in acidification and the Revelle Factor are significant, they are subject to large interannual variability (Matear and Lenton, 2008[7]). This variability has the potential to perturb the system significantly, such that far reaching changes in the ocean ecosystem may occur well in advance of those expected by simply increasing CO2 levels.

Studies of the global uptake of CO2 from the ocean by the atmosphere suggest that over time the ocean will release sufficient CO2 to amplify global warming (a positive feedback). As we have seen here the Southern Ocean is expected to evolve to act as a net sink for CO2 over the next 100 years (a negative feedback). Nevertheless, the eventual behaviour of the Southern Ocean will depend not only on what happens around Antarctica, but also on what happens in the terrestrial biosphere. Changes in the uptake of CO2 from the atmosphere by the terrestrial biosphere, particularly at mid-latitudes, could be large enough to change the pCO2 gradient between the atmosphere and the ocean, thereby affecting the response of the Southern Ocean.

Concluding remarks

The magnitude of the response of the Southern Ocean to climate change remains uncertain. Simulations from coupled climate carbon models show a large range of responses (e.g. Friedlingstein et al., 2006[17]), but do agree that the Southern Ocean will be an increased sink of atmospheric CO2 in the future and that the recent reduction in CO2 uptake will not continue. The magnitude of the total uptake is dependent on how the ocean responds to predicted increases in ocean warming and stratification, which can drive both increases in CO2 uptake through biological and export changes, and decreases through solubility and density changes. The expected increased ventilation of carbon-rich deep water, combined with uptake of atmospheric CO2, will increase the carbon content of the upper ocean, reducing the Southern Ocean’s ability to take up more CO2 in the future (through the Revelle or buffer Factor) and enhancing ocean acidification. This acidification is potentially worrisome because of its potential to impact the entire marine ecosystem. The various projections of future response are based primarily on coupled climate-carbon simulations, but such predictions need to be validated. It is therefore extremely important that strategies be developed to observe and detect change in the ocean carbon system (e.g. Lenton et al., 2006[23], 2009[24]) to complement ongoing and planned physical measurements e.g. by Argo floats.

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