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Sea ice, as the glacial cycles’ climate switch, and interhemispheric thermohaline teleconnections

Published online by Cambridge University Press:  14 September 2017

Hezi Gildor  and
Eli Tziperman
Hezi Gildor
Affiliation:
Environmental Sciences, Weizmann Institute of Science, Rehovot 76100, Israel
Eli Tziperman
Affiliation:
Environmental Sciences, Weizmann Institute of Science, Rehovot 76100, Israel
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Abstract

A box model combining the different physical components of the coupled ocean, atmosphere, sea-ice and land-ice climate system is used to study the possible role of sea ice in the glacial-interglacial oscillations. In this paper we investigate the teleconnection between the two hemispheres, and suggest a mechanism which can explain the observed Southern Ocean sea-ice variability during glacial-interglacial cycles. The teleconnection mechanism involves changes in the temperature of the water transported from the Northern to the Southern Hemisphere by the thermohaline circulation (THC), rather than the amplitude of the THC as has often been suggested. The sequence of events proposed by this model indicates that it would be especially interesting to obtain accurate information on the relative timing of sea-ice and land-ice variations. Fuller general circulation models and new sea-ice proxy data are needed to quantify the relative role of the proposed teleconnection mechanism.

Type
Sea-Ice and Climate Variability: Observations
Information
Annals of Glaciology , Volume 33 , 2001 , pp. 501 - 506
Copyright
Copyright © the Author(s) [year] 2001

1. Introduction

The glacial-interglacial cycles during the past million years were characterized by a pronounced time-scale of 100 kyr, with additional weaker spectral peaks at 41 and 23 kyr. Atmospheric CO2 also underwent changes on the same timescale, with lower concentration during glacial conditions (Reference PetitPetit and others, 1999). The existence of a dominant 100 kyr cycle in spite of the weak Milankovitch forcing at this frequency (Reference ImbrieImbrie and others, 1993) prompted alternative theories such as jumps between stable modes of the ocean-atmosphere system (Reference PaillardPaillard, 1998) and in particular of the thermohaline circulation (THC) (Reference Broecker and DentonBroecker and Denton, 1989), non-linear transfer of power from higher-frequency Milankovitch forcing (Reference Le Treut and GhilLe Treut and Ghil, 1983) and more (Reference StokesStokes, 1955; Reference SaltzmanSaltzman, 1990; Reference Muller and MacDonaldMuller and MacDonald, 1997). The asymmetric sawtooth structure of the 100 kyr glacial cycles, with slow ice build-up and rapid terminations, was attributed to phase locking to Milankovitch solar variations (Reference SaltzmanSaltzman, 1990), rapid transitions between unspecified multiple steady states of the climate system (Reference PaillardPaillard, 1998), dust-loading albedo feedbacks (Reference Peltier and MarshallPeltier and Marshall, 1995) or ice-sheet instability (Reference PollardPollard, 1983). The nearly synchronous climate variations in the Southern and Northern Hemispheres on the 100 kyr time-scale despite the asynchronous insolation forcing calls for some mechanism other than insolation.

Full general circulation models (GCMs) (Reference Manabe and BroccoliManabe and Broccoli, 1985) and intermediate models (Reference Peltier and MarshallPeltier and Marshall, 1995; Reference Weaver, Eby, Fanning and WiebeWeaver and others, 1998) have been used to calculate quasi-steady-state snapshots of the climate for fixed glaciallike forcing and orbital parameters. Yet, due to the computational cost of GCMs, highly idealized models seem to have provided us with much of our present understanding of glacial cycle dynamics (Reference WeertmanWeertman, 1976; Reference Le Treut and GhilLe Treut and Ghil, 1983; Reference SaltzmanSaltzman, 1990; Reference Saltzman and VerbitskySaltzman and Verbitsky, 1993; Reference GhilGhil, 1994; Reference PaillardPaillard, 1998; Reference Loutre and BergerLoutre and Berger, 2000). Previously used simple models were able to obtain an impressive fit to the observed proxy records (Reference Saltzman and VerbitskySaltzman and Verbitsky, 1993; Reference PaillardPaillard, 1998). However, the somewhat vague and non-explicit representation of climate processes in these models does not enable them to propose specific detailed physical mechanisms responsible for the glacial cycle dynamics.

A physical model and mechanism for the 100 kyr glacial oscillations was presented in Gildor and Tziperman (Reference Gildor and Tziperman2000, Reference Gildor and Tziperman2001), including simplified yet explicit model components for the oceanic meridional circulation, sea ice, land glaciers and atmosphere. For this study we improve the representation of the Southern Ocean dynamics. For simplicity, we force the model with seasonal varying insolation but without orbital varying parameters. The result is a plausible scenario for glacial oscillations, including the physical mechanisms involved in both the glacial and interglacial stages and the transitions between the states.

The main novel finding of the present study is a physical mechanism explaining the near synchrony in climate variation of the two hemispheres, despite the asynchronous radiation forcing (Reference Clark, Alley and PollardClark and others, 1999). During interglacial periods, the stratification in the Southern Ocean is composed of cold fresh upper water above salty and warmer North Atlantic Deep Water (NADW) arriving to the Southern Ocean from the north. Note that this water mass is relatively warm also due to mixing with surface mid-latitude water on its way from the North Atlantic. We propose that during the build-up stage of Northern Hemisphere ice sheets the deep water formed in the North Atlantic becomes gradually colder, as suggested by proxy records (Reference Schrag, Hampt and MurraySchrag and others, 1996). Similarly, the mixing with cooler glacialperiod surface water in mid-latitudes results in the subsurface deeper water arriving at the Southern Ocean colder and denser. The temperature and the amount of the upwelling water then play a key role in controlling the Southern Ocean sea-ice extent (Reference GordonGordon, 1981; Reference MartinsonMartinson, 1990): the lower deep-water temperature results in a larger sea-ice extension during cold periods. The sea-ice albedo then induces strong cooling of the atmosphere above the Southern Ocean. Thus the teleconnection between the two hemispheres in this model is not a result of the THC intensity (Reference Broecker and DentonBroecker and Denton, 1989), but mostly of the temperature of the water transported by the THC to the Southern Ocean.

2. The Model

Our coupled meridional box model, schematically shown in Figure 1, is composed of ocean, atmosphere, sea-ice and land-ice models and is very similar to the one used and described in detail by Reference Gildor and TzipermanGildor and Tziperman (2000, Reference Gildor and Tziperman2001). We therefore describe the model briefly, emphasizing the changes made for the present study. The ocean is represented in our model by three surface boxes and three deep boxes, and represents both hemispheres. The polar boxes represent the regions between 45° and the poles, while the mid-latitude box includes the regions between 45° S and 45° N. The meridional circulation through the northern box is governed by a commonly used balance between the horizontal friction and the meridional pressure gradient (Reference StommelStommel, 1961). The dynamics in the Southern Ocean, however, is different from that in the Northern Hemisphere. The upwelling of water in the south is the result of the westerly winds there, driving northward Ekman transport and thus upwelling in the Southern Ocean (Reference Toggweiler, Samuels and HeimannToggweiler and Samuels, 1993; Reference GnanadesikanGnanadesikan, 1999). Because the exact dependency of the upwelling on factors such as the intensity of the wind and on sea-ice cover is still unclear, we have chosen to fix the intensity of the THC through the southern polar box to a specified value (of 14 Sv). The ocean temperature and salinity are driven by air-sea fluxes of heat and fresh water, as well as by freshwater fluxes from land-ice ablation and runoff.

Fig. 1. The box model: (a) meridional cross-section of the box model. shaded regions represent sea ice; (b) top view of the box model.

Sea ice forms when the ocean water temperature decreases below a critical freezing temperature, and melts above that temperature. Following the observed characteristic of sea ice in both hemispheres, the sea-ice cover is assumed to grow within the northern and southern polar ocean boxes with an initial thickness of 3 and 1.5 m, respectively, and then to become thicker if the entire polar box is sea-ice covered (the sea ice never fills the entire polar boxes in the simulations presented below). Sea-ice presence and evolution affect the surface albedo and the salinity budget in the ocean, and also affect the air-sea fluxes (heat flux and evaporation) by partially insulating the ocean from the atmosphere. The equation of state is the full non-linear equation recommended by Unesco (1981).

The atmospheric model is also similar to that used by Reference Gildor and TzipermanGildor and Tziperman (2000, Reference Gildor and Tziperman2001). The lower surface of each atmospheric box is a combination of ocean, land, land ice and sea ice, each with its specified albedo. The averaged potential temperature of each atmospheric box is calculated based on the energy balance of the box, taking into account: (1) incoming solar radiation using a box albedo calculated according to the relative fraction of each lower surface type in the box; (2) outgoing longwave radiation at the top of the atmosphere; (3) heat flux into the ocean; (4) meridional atmospheric heat transport.

The meridional atmospheric moisture transport plays an important role in the temperature-precipitation feedback which, in turn, is responsible for the glacial-interglacial oscillations in our model. The precipitation-temperature feedback suggests that the increase in accumulation rate of snow over land glaciers due to a temperature increase outweighs the corresponding increase in ablation and melting. Indeed, many proxy records (Reference LoriusLorius and others, 1985; Reference AlleyAlley and others, 1993; Reference Cuffey and ClowCuffey and Glow, 1997) and GCMs (Reference Charles, Rind, Jouzel, Koester and FairbanksCharles and others, 1994) clearly show that snow accumulation over high-latitude glaciers has increased during warm periods, sometimes by a factor of 4 and up to an order of magnitude. This is probably the result of both temperature changes and changes in the atmospheric circulation (such as movements of the storm track). We use a simple parameterization which accounts for these observations (Reference Gildor and TzipermanGildor and Tziperman, 2000, Reference Gildor and Tziperman2001) and results in an increased meridional transport of humidity during warmer periods, contributing to the temperature-precipitation feedback also used by Reference Källén, Crafoord and GhilKällén and others (1979), Reference Ghil, Mullhaupt and PestiauxGhil and others (1987) and Reference GhilGhil (1994). Results of GCM experiments (Reference Charles, Rind, Jouzel, Koester and FairbanksCharles and others, 1994) and some proxy records (Reference Hebbeln, Dokken, Andersen, Hald and ElverhøiHebbeln and others, 1994) indicate that a significant amount of the precipitation feeding the glaciers comes from high latitudes (e.g. the Norwegian and Greenland seas). Therefore another source of precipitation over the land-ice sheets in the polar boxes is local evaporation from the part of the polar box ocean not covered by sea ice. Sea-ice cover during cold periods reduces this source of moisture (Reference StokesStokes, 1955; Dorm and Ewing, 1966; Reference Ruddiman and MclntyreRuddiman and Mclntyre, 1981), thus complementing the temperature-precipitation feedback.

The outgoing longwave radiation in the ith box is where σ is the Stefan-Boltzmann constant and is an emissivity coefficient which in principle depends on cloud cover, aerosol, CO2 concentration, etc., and is therefore allowed here to vary from box to box.

We have introduced a few improvements to the model for the purpose of the present study. First, the sea-ice cover in the Southern Ocean in our previous applications of this model was nearly full, with very little glacial-interglacial or seasonal sea-ice cover variability there. In order to study the tele-connection between the hemispheres, this aspect of the simulation must be improved. Another change has been to incorporate the latent heat in the Haney-type air-sea heat-flux parameterization (Reference HaneyHaney 1971), instead of the more explicit latent-heat flux representation used previously. Finally, we have changed the model to incorporate the important contribution of shortwave radiation to sea-ice thermodynamics, and the model now uses 15% of the incoming shortwave radiation, Hin, for melting of sea ice if and where it exists. The amount of shortwave radiation which reaches the sea-ice surface, namely, (1 − αc ) ( 1 − α)Hin, where a is the sea-ice albedo and ac is the cloud albedo, is divided between a part which goes back to the atmosphere as longwave radiation and turbulent heat flux, a part which is transmitted to the ocean through the ice and a part which directly causes sea-ice melting. Note that if the sea ice is not very thin and if brine pockets are neglected, the fraction of shortwave radiation transmitted to the ocean through the sea ice is quite small. This transmission of shortwave radiation to the ocean, which is also further reduced by the insulating effect of snow over the sea ice, is therefore neglected in our model and is added instead to the heating of the atmosphere. This heating does eventually contribute to the heating of the ocean by the atmosphere via the Haney-type air-sea heat flux we use. The shortwave radiation term which influences the energy balance of the sea ice can be written as (Reference Maykut and PerovichMaykut and Perovich, 1987)

where i0 is the fraction of the net shortwave radiation that does not contribute directly to surface melting. Although ac, a and i0 in reality depend on variables such as the type of the ice, its age, etc., we took them to be constants with values of 0.30, 0.65 and 0.39, respectively, giving together (1 − a) of the incoming shortwave radiation.

The model for the northern land-ice sheets, whose slow evolution provides the 100 kyr time-scale in our model, is zonally symmetric and assumes perfect plasticity so that its height is parabolic in latitude (Reference WeertmanWeertman, 1976, Reference GhilGhil, 1994). The relatively rapid bedrock deflection (Reference WeertmanWeertman, 1976; Reference Källén, Crafoord and GhilKällén and others, 1979; Reference PeltierPeltier, 1994; Reference Peltier and MarshallPeltier and Marshall, 1995) as well as the elevation desert effect and dust-loading feedback (Reference Peltier and MarshallPeltier and Marshall, 1995) are neglected. The ice sheet grows due to precipitation in the polar boxes, assumed to be evenly distributed in the box. Ice sheets can decrease as a result of ablation, ice-runoff and calving processes. In order for the ice sheet to grow, there should be excess of accumulation over ablation whether the ablation is constant or variable. We choose the simplest assumption (of constant ablation) that allows us to investigate the sea-ice switch mechanism. More complex models of the ice-sheet mass balance (Reference Huybrechts and OerlemansHuybrechts and Oerlemans, 1990; Reference Huybrechts, Letréguilly and ReehHuybrechts and others, 1991) also indicate that the assumption of constant ablation is fairly reasonable as a first approximation during the glacial-interglacial cycles. In addition, while investigating the role of orbital forcing in Reference Gildor and TzipermanGildor and Tziperman (2000) we have allowed the ablation to be a function of the summer insolation, and the oscillation mechanism has not been affected much (although the shape of the land-ice oscillation has become more realistic).

Temperature-dependent ablation may be important in human-induced greenhouse scenarios (Reference Huybrechts and OerlemansHuybrechts and Oerlemans, 1990) but is likely to be weaker than the temperature-precipitation feedback for colder climates during the past 900 kyr (Reference Källén, Crafoord and GhilKällén and others, 1979; Reference Huybrechts, Letréguilly and ReehHuybrechts and others, 1991).

As observed changes in land ice-sheet cover between glacial and interglacial occurred mostly in the Northern Hemisphere (Reference Crowley and NorthCrowley and North, 1991), land ice in the southern box is constrained in the model to cover an area equal to Antarctica, and not to change during the model integration.

3. Results

The model simulation of land-ice extent (Fig. 2) has roughly the general characteristics of the observed proxy records of land-ice volume, in terms of the 100 kyr cycles with their sawtooth structure. Let us briefly describe the mechanism of a complete glacial-interglacial cycle as analyzed in detail in Reference Gildor and TzipermanGildor and Tziperman (2000, Reference Gildor and Tziperman2001): as the land ice begins to grow from its minimum point (Fig. 3a; 110 kyr) the ocean in the northern polar box is ice-free (Fig. 3b) and sea-ice extent in the Southern Ocean is minimal (Fig. 3c). The atmospheric (not shown) and ocean temperatures (Fig. 3f) in the northern box are rather mild. Snow accumulation over glaciers exceeds the ablation, melting and calving term (Fig. 3e), and therefore the Northern Hemisphere land ice gradually grows. The resulting slow increase in land albedo slowly reduces the temperature of the atmosphere and of the ocean (Fig. 3f) in the corresponding northern polar box. When the ocean sea-surface temperature (Fig. 3f) reaches the freezing temperature, sea ice forms very rapidly (Fig. 3b; 35 kyr). The creation of sea ice further increases the albedo, induces a further reduction of atmospheric temperature and results in the creation of more sea ice (positive feedback). In about 20 years, almost the entire northern polar box ocean surface is covered by sea ice. Dramatic sea-ice response to small climate changes has also been seen in previous studies (Reference ThorndikeThorndike, 1992; Reference Flato and BrownFlato and Brown, 1996). Sea ice stops growing when it isolates enough of the polar ocean from the cold atmosphere, reducing the air-sea cooling that leads to the sea-ice formation. The sea-ice "switch" is now turned to "on". Note, though, that even during the model glacial maximum there is a strong seasonal cycle in the model sea-ice extension, so the sea-ice cover is significantly smaller during summer, consistent with recent proxy measurements (Reference Weinelt, Sarnthein, Pflaumann, Schultz, Jung and ErlenkeuserWeinelt and others, 1996).

Fig. 2. Time series of model land-ice extent in the northern polar box as a fraction of land area.

Fig. 3. Time series of model result during one complete glacial-interglacial cycle. (a) northern land-ice extent as a fraction of the polar land box area; (b) northern sea-ice extent as a frac tion of polar ocean box area; (c) southern sea-ice extent as a fraction of polar ocean box area; (d) thc through the northern polar boxes (106 m3 s−1); (e) source term (solid line) and sink term (dashed line), for northern land glacier (106m3s−1); (f) temperature in the northern upper polar oceanic box (°c); ( g) temperature in the mid-latitude deep oceanic box (°c); ( h) temperature in the southern deeper polar oceanic box (°c).

At this stage, the average global temperature is at its lowest point, land ice-sheet and winter sea-ice extents are maximal, and the system is at a glacial maximum. The low atmospheric temperature reduces the poleward atmospheric moisture flux to about half its maximum value. Similarly, the sea-ice cover limits the moisture extraction from the polar ocean box and the corresponding snow accumulation over the land ice (Reference AlleyAlley and others, 1993; Reference Cuffey and ClowCuffey and Glow, 1997). As ablation, glacier melting, calving and runoff proceed as before (Fig. 3e), the glaciers start retreating. The albedo decreases again and the atmospheric temperature rises slowly. This is the beginning of the termination stage of the glacial period. Once the deep ocean warms enough and allows the upper ocean to warm as well, the sea ice melts within about 40 years (Fig. 3b; around 13 kyr). The sea-ice switch is now turned to "off", the temperature of both the atmosphere and the ocean increases, and the system has completed a full glacial cycle.

Note that in this mechanism the glacial oscillations exist due to a self-sustained internal variability of the physical climate system. In Reference Gildor and TzipermanGildor and Tziperman (2000) we have shown that Milankovitch forcing provides only the phase locking of the 100 kyr variability In Gildor andTziperman (in press) we combine the physical climate system model with an ocean biochemistry model and variable atmospheric CO2. We show there that glacial-interglacial CO2 variations amplify the glacial-interglacial cycles which exist even without the CO2 variations. This amplifying role of the atmospheric CO2 is consistent with the recent interpretation of the Vostok record (Reference PetitPetit and others, 1999).

The 100 kyr signal seen in proxy records is clearly global, but the precise phasing between them and the detailed mechanisms which connect the two hemispheres are still an open question (Reference Clark, Alley and PollardClark and others, 1999). Changes in the intensity of the THC have been proposed as a way for the North Atlantic climate to affect to some degree the Southern Ocean. The present model shows a supplementary way in which Northern Hemisphere climate can be propagated to the Southern Hemisphere through the effects of NADW adverted to the Southern Ocean. The temperature of the NADW is dictated by the amount of land ice in the northern box (Fig. 3a) through the albedo effect of the land ice on the Northern Hemisphere atmospheric and oceanic temperatures. As northern land ice expands, the temperature of the NADW forming in the northern box and flowing southward decreases (Fig. 3f-h), consistent with observations suggesting cooling of down to 4°C in the deep Tropical Atlantic (Reference Schrag, Hampt and MurraySchrag and others, 1996). Once reaching the Southern Ocean, the colder upwelling NADW (Fig. 3h) causes the sea-ice extension in the Southern Ocean to increase during glacial (Fig. 3c). This teleconnection mechanism between the two hemispheres through the temperature of the NADW supplements the possible mechanism that relies on the amplitude of the THC. Finally, we note that the changes to the temperature of the deep water in the Southern Ocean also affect the stratification and therefore the vertical mixing there. The effects of this mechanism on both the ocean biochemistry and the sea-ice extent are investigated in Gildor andTziperman (in press).

4. Conclusion

This paper extends the sea-ice switch mechanism of the 100 kyr glacial-interglacial cycles (Reference Gildor and TzipermanGildor and Tziperman, 2000, Reference Gildor and Tziperman2001) to account for interhemispheric climate connectivity. In the interhemispheric teleconnection mechanism proposed here, cooling signals from the Northern Hemisphere, which result from the growth of Northern Hemisphere land-ice sheets, are transferred to the deep ocean by affecting the temperature of the NADW sinking in the northern high latitudes. The NADW cooling, in turn, is transported by the THC and affects the Southern Ocean. As sea-ice extension in the Southern Ocean is largely affected by the temperature of the deep-water upwelling there, the lower temperature of the deep water causes an increase in sea-ice extension (and albedo) in the Southern Hemisphere during glacial times.

An important aspect of the model solution is the occurrence of Northern Hemisphere sea ice in phase with the land-ice deglaciation. The model also predicts that deglaciation-related warming of the Southern Ocean may have occurred up to a few hundred years after that of the Northern Hemisphere, as this would be the time it takes the THC to transfer the signal from the Northern Hemisphere. There are some proxy data indications that the Southern Ocean warming of sea surface temperature may have occurred prior to the deglaciation of the Northern Hemisphere, at least on short time-scales (Reference LabeyrieLabeyrie and others, 1996). Opposite proxy evidence for this interhemispheric phasing, more consistent with our results, exists as well (Reference SteigSteig and others, 1998; Reference Clark, Alley and PollardClark and others, 1999). In general, it seems that presently available sea-ice proxy data still lack the spatial and temporal resolution which would enable resolution of the sea-ice phase relative to that of the major land-ice deglaciation. Some studies suggest that at least a part of deglaciation has occurred during periods with extensive sea-ice cover (Reference De Vernal and Pedersende Vernal and Pedersen, 1997; Reference De Vernal and Hillaire-Marcelde Vernal and Hillaire-Marcel, 2000). Given the uncertainties of available proxy records, and especially given the lack of a satisfactory detailed physical mechanism for the glacial cycles (as opposed to just a fit to the available proxies) and for the teleconnection between the two hemispheres, we argue that it would be useful to keep an open mind regarding a possible sea-ice control of glacial dynamics, while examining both the available proxy record and new proxy data that become available.

The proposed mechanisms for both the 100 kyr glacial oscillations of Reference Gildor and TzipermanGildor and Tziperman (2000, Reference Gildor and Tziperman2001) and the interhemispheric teleconnection via deep-water temperature explored in this paper are clearly speculative at this stage, and it should be clear that we do not promote these as the only mechanism responsible for the 100 kyr glacial oscillations and for the synchronization of the two hemispheres. CO2 feedbacks which could transfer information between the hemispheres (Reference GenthonGenthon and others, 1987), or an explicit sea-level-glacier instability mechanism which could be especially important for the Antarctic ice sheet (Reference Huybrechts and OerlemansHuybrechts and Oerlemans, 1990; Reference PatersonPaterson, 1994) clearly contributed to globalizing climate changes. Another interhemispheric teleconnection mechanism not included here is the possible effect of Southern Ocean winds on the NADW formation rate (Reference Toggweiler, Samuels and HeimannToggweiler and Samuels, 1993). The omission of this mechanism may contribute to the small THC variability seen in our model (Fig. 3d). We wish to emphasize the need for a climate switch mechanism to supplement THC instabilities which do not seem to be able to account for global climate changes during glacial-interglacial cycles. Note that in the scenario proposed here, the THC plays an important role in the teleconnection between the hemispheres, but it is the sea-ice switch that shifts the climate system from one phase of the glacial oscillation to another. Fuller general circulation models and new sea-ice proxy data are clearly needed to quantify the relative role of the proposed role of sea ice and of the deep THC temperature.

Acknowledgements

We thank M. A. Morales Maqueda, M. Montoya and an anonymous reviewer for their most useful and constructive comments. This work is partially supported by the Israeli-US. Binational Science Foundation.

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Fig. 1. The box model: (a) meridional cross-section of the box model. shaded regions represent sea ice; (b) top view of the box model.

Figure 1

Fig. 2. Time series of model land-ice extent in the northern polar box as a fraction of land area.

Figure 2

Fig. 3. Time series of model result during one complete glacial-interglacial cycle. (a) northern land-ice extent as a fraction of the polar land box area; (b) northern sea-ice extent as a frac tion of polar ocean box area; (c) southern sea-ice extent as a fraction of polar ocean box area; (d) thc through the northern polar boxes (106 m3 s−1); (e) source term (solid line) and sink term (dashed line), for northern land glacier (106m3s−1); (f) temperature in the northern upper polar oceanic box (°c); ( g) temperature in the mid-latitude deep oceanic box (°c); ( h) temperature in the southern deeper polar oceanic box (°c).