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1.
The stability of the Atlantic thermohaline circulation against meltwater input is investigated in a coupled ocean-atmosphere
general circulation model. The meltwater input to the Labrador Sea is increased linearly for 250 years to a maximum input
of 0.625 Sv and then reduced again to 0 (both instantaneously and linearly decreasing over 250 years). The resulting freshening
forces a shutdown of the formation of North Atlantic deepwater and a subsequent reversal of the thermohaline circulation of
the Atlantic, filling the deep Atlantic with Antarctic bottom water. The change in the overturning pattern causes a drastic
reduction of the Atlantic northward heat transport, resulting in a strong cooling with maximum amplitude over the northern
North Atlantic and a southward shift of the sea-ice margin in the Atlantic. Due to the increased meridional temperature gradient,
the intertropical convergence zone over the Atlantic is displaced southward and the westerlies in the Northern Hemisphere
gain strength. We identify four main feedbacks affecting the stability of the thermohaline circulation: the change in the
overturning circulation of the Atlantic leads to longer residence times of the surface water in high-northern latitudes, which
allows them to accumulate more precipitation and runoff from the continents. As a consequence the stratification in the North
Atlantic becomes more stable. This effect is further amplified by an enhanced northward atmospheric water vapour transport,
which increases the freshwater input into the North Atlantic. The reduced northward oceanic heat transport leads to colder
sea-surface temperatures and an intensification of the atmospheric cyclonic circulation over the Norwegian Sea. The associated
Ekman transports cause increased upwelling and increased freshwater export with the East Greenland Current. Both the cooling
and the wind-driven circulation changes largely compensate for the effects of the first two feedbacks. The wind-stress feedback
destabilizes modes without deep water formation in the North Atlantic, but has been neglected in almost all studies so far.
After the meltwater input stops, the North Atlantic deepwater formation resumed in all experiments and the meridional overturning
returned within 200 years to a conveyor belt pattern. This happened although the formation of North Atlantic deep water was
suppressed in one experiment for more than 300 years and the Atlantic overturning had settled into a circulation pattern with
Antarctic bottom water as the only source of deep water. It is a clear indication that cooling and wind-stress feedback are
more effective, at least in our model, than advection feedback and increased atmospheric water vapour transport. We conclude
that the conveyor belt-type thermohaline circulation seems to be much more stable than hitherto assumed from experiments with
simpler models.
Received 31 January 1996/Accepted 22 August 1996 相似文献
2.
Recent studies have indicated that the multidecadal variations of the Atlantic Warm Pool (AWP) can induce a significant freshwater change in the tropical North Atlantic Ocean. In this paper, the potential effect of the AWP-induced freshwater flux on the Atlantic Meridional Overturning Circulation (AMOC) is studied by performing a series of ocean–sea ice model experiments. Our model experiments demonstrate that ocean response to the anomalous AWP-induced freshwater flux is primarily dominated by the basin-scale gyre circulation adjustments with a time scale of about two decades. The positive (negative) freshwater anomaly leads to an anticyclonic (cyclonic) circulation overlapping the subtropical gyre. This strengthens (weakens) the Gulf Stream and the recirculation in the interior ocean, thus increases warm (cold) water advection to the north and decreases cold (warm) water advection to the south, producing an upper ocean temperature dipole in the midlatitude. As the freshwater (salty water) is advected to the North Atlantic deep convection region, the AMOC and its associated northward heat transport gradually decreases (increases), which in turn lead to an inter-hemispheric SST seesaw. In the equilibrium state, a comma-shaped SST anomaly pattern develops in the extratropical region, with the largest amplitude over the subpolar region and an extension along the east side of the basin and into the subtropical North Atlantic. Based on our model experiments, we argue that the multidecadal AWP-induced freshwater flux can affect the AMOC, which plays a negative feedback role that acts to recover the AMOC after it is weakened or strengthened. The sensitivity of AMOC response to the AWP-induced freshwater forcing amplitude is also examined and discussed. 相似文献
3.
The role of salinity in the decadal variability of the North Atlantic meridional overturning circulation 总被引:1,自引:1,他引:0
An OGCM hindcast is used to investigate the linkages between North Atlantic Ocean salinity and circulation changes during
1963–2003. The focus is on the eastern subpolar region consisting of the Irminger Sea and the eastern North Atlantic where
a careful assessment shows that the simulated interannual to decadal salinity changes in the upper 1,500 m reproduce well
those derived from the available record of hydrographic measurements. In the model, the variability of the Atlantic meridional
overturning circulation (MOC) is primarily driven by changes in deep water formation taking place in the Irminger Sea and,
to a lesser extent, the Labrador Sea. Both are strongly influenced by the North Atlantic Oscillation (NAO). The modeled interannual
to decadal salinity changes in the subpolar basins are mostly controlled by circulation-driven anomalies of freshwater flux
convergence, although surface salinity restoring to climatology and other boundary fluxes each account for approximately 25%
of the variance. The NAO plays an important role: a positive NAO phase is associated with increased precipitation, reduced
northward salt transport by the wind-driven intergyre gyre, and increased southward flows of freshwater across the Greenland–Scotland
ridge. Since the NAO largely controlled deep convection in the subpolar gyre, fresher waters are found near the sinking region
during convective events. This markedly differs from the active influence on the MOC that salinity exerts at decadal and longer
timescales in most coupled models. The intensification of the MOC that follows a positive NAO phase by about 2 years does
not lead to an increase in the northward salt transport into the subpolar domain at low frequencies because it is cancelled
by the concomitant intensification of the subpolar gyre which shifts the subpolar front eastward and reduces the northward
salt transport by the North Atlantic Current waters. This differs again from most coupled models, where the gyre intensification
precedes that of the MOC by several years. 相似文献
4.
To understand the influence of the Bering Strait on the World Ocean’s circulation, a model sensitivity analysis is conducted.
The numerical experiments are carried out with a global, coupled ice–ocean model. The water transport through the Bering Strait
is parametrized according to the geostrophic control theory. The model is driven by surface fluxes derived from bulk formulae
assuming a prescribed atmospheric seasonal cycle. In addition, a weak restoring to observed surface salinities is applied
to compensate for the global imbalance of the imposed surface freshwater fluxes. The freshwater flux from the North Pacific
to the North Atlantic associated with the Bering Strait throughflow seems to be an important element in the freshwater budget
of the Greenland and Norwegian seas and of the Atlantic. This flux induces a freshening of the North Atlantic surface waters,
which reduces the convective activity and leads to a noticeable (6%) weakening of the thermohaline conveyor belt. It is argued
that the contrasting results obtained by Reason and Power are due to the type of surface boundary conditions they used.
Received: 27 October 1995/Accepted: 20 November 1996 相似文献
5.
《大气与海洋》2013,51(2):81-92
Abstract Evidence based on numerical simulations is presented for a strong correlation between the North Atlantic Oscillation (NAO) and the North Atlantic overturning circulation. Using an ensemble of numerical experiments with a coupled ocean‐atmosphere model including both natural and anthropogenic forcings, it is shown that the weakening of the thermohaline circulation (THC) could be delayed in response to a sustained upward trend in the NAO, which was observed over the last three decades of the twentieth century, 1970–99. Overall warming and enhanced horizontal transports of heat from the tropics to the subpolar North Atlantic overwhelm the NAO‐induced cooling of the upper ocean layers due to enhanced fluxes of latent and sensible heat, so that the net effect of warmed surface ocean temperatures acts to increase the vertical stability of the ocean column. However, the strong westerly winds cause increased evaporation from the ocean surface, which leads to a reduced fresh water flux over the western part of the North Atlantic. Horizontal poleward transport of salinity anomalies from the tropical Atlantic is the major contributor to the increasing salinities in the sinking regions of the North Atlantic. The effect of positive salinity anomalies on surface ocean density overrides the opposing effect of enhanced warming of the ocean surface, which causes an increase in surface density in the Labrador Sea and in the ocean area south of Greenland. The increased density of the upper ocean layer leads to deeper convection in the Labrador Sea and in the western North Atlantic. With a lag of four years, the meridional overturning circulation of the North Atlantic shows strengthening as it adjusts to positive density anomalies and enhanced vertical mixing. During the positive NAO trend, the salinity‐driven density instability in the upper ocean, due to both increased northward ocean transports of salinity and decreased atmospheric freshwater fluxes, results in a strengthening overturning circulation in the North Atlantic when the surface atmospheric temperature increases by 0.3°C and the ocean surface temperature warms by 0.5° to 1°C. 相似文献
6.
A box model of the inter-hemispheric Atlantic meridional overturning circulation is developed, including a variable pycnocline depth for the tropical and subtropical regions. The circulation is forced by winds over a periodic channel in the south and by freshwater forcing at the surface. The model is aimed at investigating the ocean feedbacks related to perturbations in freshwater forcing from the atmosphere, and to changes in freshwater transport in the ocean. These feedbacks are closely connected with the stability properties of the meridional overturning circulation, in particular in response to freshwater perturbations. A separate box is used for representing the region north of the Antarctic circumpolar current in the Atlantic sector. The density difference between this region and the north of the basin is then used for scaling the downwelling in the north. These choices are essential for reproducing the sensitivity of the meridional overturning circulation observed in general circulation models, and therefore suggest that the southernmost part of the Atlantic Ocean north of the Drake Passage is of fundamental importance for the stability of the meridional overturning circulation. With this configuration, the magnitude of the freshwater transport by the southern subtropical gyre strongly affects the response of the meridional overturning circulation to external forcing. The role of the freshwater transport by the overturning circulation (M ov ) as a stability indicator is discussed. It is investigated under which conditions its sign at the latitude of the southern tip of Africa can provide information on the existence of a second, permanently shut down, state of the overturning circulation in the box model. M ov will be an adequate indicator of the existence of multiple equilibria only if salt-advection feedback dominates over other processes in determining the response of the circulation to freshwater anomalies. M ov is a perfect indicator if feedbacks other than salt-advection are negligible. 相似文献
7.
Seawater property changes in the North Atlantic Ocean affect the Atlantic meridional overturning circulation (AMOC), which transports warm water northward from the upper ocean and contributes to the temperate climate of Europe, as well as influences climate globally. Previous observational studies have focused on salinity and freshwater variability in the sinking region of the North Atlantic, since it is believed that a freshening North Atlantic basin can slow down or halt the flow of the AMOC. Here we use available data to show the importance of how density patterns over the upper ocean of the North Atlantic affect the strength of the AMOC. For the long-term trend, the upper ocean of the subpolar North Atlantic is becoming cooler and fresher, whereas the subtropical North Atlantic is becoming warmer and saltier. On a multidecadal timescale, the upper ocean of the North Atlantic has generally been warmer and saltier since 1995. The heat and salt content in the subpolar North Atlantic lags that in the subtropical North Atlantic by about 8–9 years, suggesting a lower latitude origin for the temperature and salinity anomalies. Because of the opposite effects of temperature and salinity on density for both long-term trend and multidecadal timescales, these variations do not result in a density reduction in the subpolar North Atlantic for slowing down the AMOC. Indeed, the variations in the meridional density gradient between the subpolar and subtropical North Atlantic Ocean suggest that the AMOC has become stronger over the past five decades. These observed results are supported by and consistent with some oceanic reanalysis products. 相似文献
8.
T. M. Lenton R. Marsh A. R. Price D. J. Lunt Y. Aksenov J. D. Annan T. Cooper-Chadwick S. J. Cox N. R. Edwards S. Goswami J. C. Hargreaves P. P. Harris Z. Jiao V. N. Livina A. J. Payne I. C. Rutt J. G. Shepherd P. J. Valdes G. Williams M. S. Williamson A. Yool 《Climate Dynamics》2007,29(6):591-613
We have used the Grid ENabled Integrated Earth system modelling (GENIE) framework to undertake a systematic search for bi-stability
of the ocean thermohaline circulation (THC) for different surface grids and resolutions of 3-D ocean (GOLDSTEIN) under a 3-D
dynamical atmosphere model (IGCM). A total of 407,000 years were simulated over a three month period using Grid computing.
We find bi-stability of the THC despite significant, quasi-periodic variability in its strength driven by variability in the
dynamical atmosphere. The position and width of the hysteresis loop depends on the choice of surface grid (longitude-latitude
or equal area), but is less sensitive to changes in ocean resolution. For the same ocean resolution, the region of bi-stability
is broader with the IGCM than with a simple energy-moisture balance atmosphere model (EMBM). Feedbacks involving both ocean
and atmospheric dynamics are found to promote THC bi-stability. THC switch-off leads to increased import of freshwater at
the southern boundary of the Atlantic associated with meridional overturning circulation. This is counteracted by decreased
freshwater import associated with gyre and diffusive transports. However, these are localised such that the density gradient
between North and South is reduced tending to maintain the THC off state. THC switch-off can also generate net atmospheric
freshwater input to the Atlantic that tends to maintain the off state. The ocean feedbacks are present in all resolutions,
across most of the bi-stable region, whereas the atmosphere feedback is strongest in the longitude–latitude grid and around
the transition where the THC off state is disappearing. Here the net oceanic freshwater import due to the overturning mode
weakens, promoting THC switch-on, but the atmosphere counteracts this by increasing net freshwater input. This increases the
extent of THC bi-stability in this version of the model.
Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. 相似文献
9.
In this study we investigate the role of heat, freshwater and momentum fluxes in changing the oceanic climate and thermohaline
circulation as a consequence of increasing atmospheric CO2 concentration. Two baseline integrations with a fully coupled ocean atmosphere general circulation model with either fixed
or increasing atmospheric CO2 concentrations have been performed. In a set of sensitivity experiments either freshwater (precipitation, evaporation and
runoff from the continents) and/or momentum fluxes were no longer simulated, but prescribed according to one of the fully
coupled baseline experiments. This approach gives a direct estimate of the contribution from the individual flux components.
The direct effect of surface warming and the associated feedbacks in ocean circulation are the dominant processes in weakening
the Atlantic thermohaline circulation in our model. The relative contribution of momentum and freshwater fluxes to the total
response turned out to be less than 25%, each. Changes in atmospheric water vapour transport lead to enhanced freshwater input
into middle and high latitudes, which weakens the overturning. A stronger export of freshwater from the Atlantic drainage
basin to the Indian and Pacific ocean, on the other hand, intensifies the Atlantic overturning circulation. In total the modified
freshwater fluxes slightly weaken the Atlantic thermohaline circulation. The contribution of the modified momentum fluxes
has a similar magnitude, but enhances the formation of North Atlantic deep water. Salinity anomalies in the Atlantic as a
consequence of greenhouse warming stem in almost equal parts from changes in net freshwater fluxes and from changes in ocean
circulation caused by the surface warming due to atmospheric heat fluxes. Important effects of the momentum fluxes are a poleward
shift of the front between Northern Hemisphere subtropical and subpolar gyres and a southward shift in the position of the
Antarctic circumpolar current, with a clear signal in sea level.
Received: 3 May 1999 / Accepted: 11 December 1999 相似文献
10.
Under external heating forcing in the Southern Ocean, climate models project anomalous northward atmosphere heat transport (AHT) across the equator, accompanied by a southward shift of the intertropical convergence zone (ITCZ). Comparison between a fully coupled and a slab ocean model shows that the inclusion of active ocean dynamics tends to partition the cross-equatorial energy transport and significantly reduce the ITCZ shift response by a factor of 10, a finding which supports previous studies. To understand how ocean dynamics damps the ITCZ's response to an imposed thermal heating in the Southern Ocean, we examine the ocean heat transport (OHT) and ocean circulation responses in a set of fully coupled experiments. Results show that both the Indo-Pacific and the Atlantic contribute to transport energy across the equator mainly through its Eulerian-mean component. However, different from previous studies that linked the changes in OHT to the changes in the wind-driven subtropical cells or the Atlantic meridional overturning circulation (AMOC), our results show that the cross-equatorial OHT anomaly is due to a broad clockwise overturning circulation anomaly below the subtropical cells (approximately bounded by the 5℃ to 20℃ isotherms and 50°S to 10°N). Further elimination of the wind-driven component, conducted by prescribing the climatological wind stress in the Southern Ocean heat perturbation experiments, leads to little change in OHT, suggesting that the OHT response is predominantly thermohaline-driven by air-sea thermal interactions. 相似文献
11.
The South Atlantic response to a collapse of the North Atlantic meridional overturning circulation (AMOC) is investigated in the ECHAM5/MPI-OM climate model. A reduced Agulhas leakage (about 3.1?Sv; 1?Sv?=?106?m3?s?1) is found to be associated with a weaker Southern Hemisphere (SH) supergyre and Indonesian throughflow. These changes are due to reduced wind stress curl over the SH supergyre, associated with a weaker Hadley circulation and a weaker SH subtropical jet. The northward cross-equatorial transport of thermocline and intermediate waters is much more strongly reduced than Agulhas leakage in relation with an AMOC collapse. A cross-equatorial gyre develops due to an anomalous wind stress curl over the tropics that results from the anomalous sea surface temperature gradient associated with reduced ocean heat transport. This cross-equatorial gyre completely blocks the transport of thermocline waters from the South to the North Atlantic. The waters originating from Agulhas leakage flow somewhat deeper and most of it recirculates in the South Atlantic subtropical gyre, leading to a gyre intensification. This intensification is consistent with the anomalous surface cooling over the South Atlantic. Most changes in South Atlantic circulation due to global warming, featuring a reduced AMOC, are qualitatively similar to the response to an AMOC collapse, but smaller in amplitude. However, the increased northward cross-equatorial transport of intermediate water relative to thermocline water is a strong fingerprint of an AMOC collapse. 相似文献
12.
1998年区域性水汽输送及对流活动与副高活动变异的相关特征(英) 总被引:3,自引:1,他引:3
根据1998年NCEP逐日资料和TBB逐日资料,探讨了低纬度对流活动和副高周边水汽输送及其对流活动对夏季西太平洋副热带高压季节性北跳、南撤的影响效应。研究表明:低纬热带对流加强,且110°-150°E地区的南北向垂直经圈环流下沉区北移,夏季西太平洋副热带高压有北跳现象。另外,诊断结果亦表明西太平洋副高周边纬向水汽输送的显著减弱亦预示将出现副高的北跳,而西太平洋地区低纬经向水汽输送减少一候之后,副高南撤。研究结果表明西太平洋副高北跳、南撤与低纬度的对流潜热释放、中纬西太平洋副高周边的水汽输送及其对流活动存在密切的关系。数值模拟结果进一步证实上述副高活动变异与前期水汽输送及其对流特征的相关关系。 相似文献
13.
James R. Miller Gary L. Russell Lie-Ching Tsang 《Dynamics of Atmospheres and Oceans》1983,7(2):95-109
Mean annual estimates of the oceanic poleward energy transport are obtained using a global atmospheric general circulation model. The computations are carried out by using the atmospheric model to determine the net annual heat flux into the ocean on an 8° × 10° grid. Assuming no net annual heat storage, the annual surface heat fluxes into any zonal band must be accompanied by a corresponding meridional heat transport in the ocean. Heat is transported northward at all latitudes in the Atlantic Ocean and is transported poleward in both hemispheres in the Pacific Ocean. To account for the net northward transport throughout the Atlantic, heat is transported into the Atlantic from the Indian and Pacific basins. The results are compared with several recent direct and indirect calculations of oceanic meridional heat transports. 相似文献
14.
Key features of the IPSL ocean atmosphere model and its sensitivity to atmospheric resolution 总被引:9,自引:8,他引:1
Olivier Marti P. Braconnot J.-L. Dufresne J. Bellier R. Benshila S. Bony P. Brockmann P. Cadule A. Caubel F. Codron N. de Noblet S. Denvil L. Fairhead T. Fichefet M.-A. Foujols P. Friedlingstein H. Goosse J.-Y. Grandpeix E. Guilyardi F. Hourdin A. Idelkadi M. Kageyama G. Krinner C. Lévy G. Madec J. Mignot I. Musat D. Swingedouw C. Talandier 《Climate Dynamics》2010,34(1):1-26
This paper presents the major characteristics of the Institut Pierre Simon Laplace (IPSL) coupled ocean–atmosphere general circulation model. The model components and the coupling methodology are described, as well as the main characteristics of the climatology and interannual variability. The model results of the standard version used for IPCC climate projections, and for intercomparison projects like the Paleoclimate Modeling Intercomparison Project (PMIP 2) are compared to those with a higher resolution in the atmosphere. A focus on the North Atlantic and on the tropics is used to address the impact of the atmosphere resolution on processes and feedbacks. In the North Atlantic, the resolution change leads to an improved representation of the storm-tracks and the North Atlantic oscillation. The better representation of the wind structure increases the northward salt transports, the deep-water formation and the Atlantic meridional overturning circulation. In the tropics, the ocean–atmosphere dynamical coupling, or Bjerknes feedback, improves with the resolution. The amplitude of ENSO (El Niño-Southern oscillation) consequently increases, as the damping processes are left unchanged. 相似文献
15.
A possible feedback mechanism involving the Arctic freshwater, the Arctic sea ice, and the North Atlantic Drift 总被引:1,自引:0,他引:1
Model studies point to enhanced warming and to increased freshwater fluxes to high northern latitudes in response to global warming. In order to address possible feedbacks in the ice-ocean system in response to such changes, the combined effect of increased freshwater input to the Arctic Ocean and Arctic warming--the latter manifested as a gradual melting of the Arctic sea ice--is examined using a 3-D isopycnic coordinate ocean general circulation model. A suite of three idealized experiments is carried out: one control integration, one integration with a doubling of the modern Arctic river runoff, and a third more extreme case, where the river runoff is five times the modern value. In the two freshwater cases, the sea ice thickness is reduced by 1.5-2 m in the central Arctic Ocean over a 50-year period. The modelled ocean response is qualitatively the same for both perturbation experiments: freshwater propagates into the Atlantic Ocean and the Nordic Seas, leading to an initial weakening of the North Atlantic Drift.Furthermore, changes in the geostrophic currents in the central Arctic and melting of the Arctic sea ice lead to an intensified Beaufort Gyre, which in turn increases the southward volume transport through the Canadian Archipelago. To compensate for this southward transport of mass, more warm and saline Atlantic water is carried northward with the North Atlantic Drift. It is found that the increased transport of salt into the northern North Atlantic and the Nordic Seas tends to counteract the impact of the increased freshwater originating from the Arctic, leading to a stabilization of the North Atlantic Drift. 相似文献
16.
The hydrological cycle can influence climate through a great variety of processes. A good representation of the hydrological cycle in climate models is therefore crucial. Attempts to analyse the global hydrological cycle are hampered by a deficiency of suitable observations, particularly over the oceans. Fully coupled general circulation models are potentially powerful tools in interpreting the limited observational data in the context of large-scale freshwater exchanges. We have looked at large-scale aspects of the global freshwater budget in a simulation, of over 1000 years, by the Hadley Centre coupled climate model (HadCM3). Many aspects of the global hydrological cycle are well represented, but the model hydrological cycle appears to be too strong, with overly large precipitation and evaporation components in comparison with the observational datasets we have used. We show that the ocean basin-scale meridional transports of freshwater come into near balance with the surface freshwater fluxes on a time scale of about 400 years, with the major change being a relative increase of freshwater transport from the Southern Ocean into the Atlantic Ocean. Comparison with observations, supported by sensitivity tests, suggests that the major cause of a drift to more saline condition in the model Atlantic is an overestimate of evaporation, although other freshwater budget components may also play a role. The increase in ocean freshwater transport into the Atlantic during the simulation, primarily coming from the overturning circulation component, which changes from divergent to convergent, acts to balance this freshwater budget deficit. The stability of the thermohaline circulation in HadCM3 may be affected by these freshwater transport changes and this question is examined in the context of an existing conceptual model. 相似文献
17.
Long-term precipitation variability in Morocco and the link to the large-scale circulation in recent and future climates 总被引:1,自引:0,他引:1
Summary ?Monthly precipitation data from the Global Historical Climatology Network for 42 stations in Morocco and its vicinity are
investigated with respect to baroclinicity, storm track and cyclone activity, moisture transports, North Atlantic Oscillation
(NAO) variations, and different circulation types by means of correlation and composite studies. The results are related to
a climate change scenario from an ECHAM4/OPYC3 transient greenhouse gas only (GHG) simulation. Precipitation in northwestern
Morocco shows a clear link to the baroclinic activity over the North Atlantic during boreal winter (DJF). In large precipitation
months the North Atlantic storm track is shifted southward, more westerly and northwesterly circulation situations occur and
moisture transports from the Atlantic are enhanced. The occurrence of local cyclones and upper-level troughs is more frequent
than in low precipitation months. The negative correlation to the NAO is relatively strong, especially with Gibraltar as a
southern pole (−0.71). The northward shift of the storm track and eastward shift of the Azores High predicted by the ECHAM
model for increasing GHG concentrations would therefore be associated with decreasing precipitation and potentially serious
impacts for the future water supply for parts of Morocco. In the region south of the Atlas mountains, moisture transports
from the Atlantic along the southern flank of the Atlas Mountains associated with cyclones west of Morocco and the Iberian
Peninsula can be identified as a decisive factor for precipitation. Northeastern Morocco and Northwestern Algeria, however,
is rather dominated by the influence of cyclones over the Western Mediterranean that are associated with a strong northwesterly
moisture transport. As both regions appear to be less dependent on the North Atlantic storm track and more on local processes,
a straight forward interpretation of the large-scale changes predicted by the ECHAM4/OPYC3 cannot be done without the application
of down-scaling methods in the future.
Received July 19, 2001; revised May 31, 2002 相似文献
18.
Sea level change predicted by the CMIP5 atmosphere–ocean general circulation models (AOGCMs) is not spatially homogeneous. In particular, the sea level change in the North Atlantic is usually characterised by a meridional dipole pattern with higher sea level rise north of 40°N and lower to the south. The spread among models is also high in that region. Here we evaluate the role of surface buoyancy fluxes by carrying out simulations with the FAMOUS low-resolution AOGCM forced by surface freshwater and heat flux changes from CO2-forced climate change experiments with CMIP5 AOGCMs, and by a standard idealised surface freshwater flux applied in the North Atlantic. Both kinds of buoyancy flux change lead to the formation of the sea level dipole pattern, although the effect of the heat flux has a greater magnitude, and is the main cause of the spread of results among the CMIP5 models. By using passive tracers in FAMOUS to distinguish between additional and redistributed buoyancy, we show that the enhanced sea level rise north of 40°N is mainly due to the direct steric effect (the reduction of sea water density) caused by adding heat or freshwater locally. The surface buoyancy forcing also causes a weakening of the Atlantic meridional overturning circulation, and the consequent reduction of the northward ocean heat transport imposes a negative tendency on sea level rise, producing the reduced rise south of 40°N. However, unlike previous authors, we find that this indirect effect of buoyancy forcing is generally less important than the direct one, except in a narrow band along the east coast of the US, where it plays a major role and leads to sea level rise, as found by previous authors. 相似文献
19.
The stability of the MOC as diagnosed from model projections for pre-industrial, present and future climates 总被引:1,自引:1,他引:0
The stability of the Atlantic meridional overturning circulation (MOC) is investigated for various climate scenario runs, using data from the CMIP3 archive of coupled atmosphere-ocean models. Apart from atmospheric feedbacks, the sign of the salt flux into the Atlantic basin that is carried by the MOC determines whether the MOC is in the single or multiple equilibria regime. This salt advection feedback is analyzed by diagnosing the freshwater and salt budgets for the combined Atlantic and Arctic basins. Consistent with the finding that almost all coupled climate models recover from hosing experiments, it is found that most models feature a negative salt advection feedback in their pre-industrial climate: freshwater perturbations are damped by this feedback, excluding the existence of a stable off-state for the MOC. All models feature enhanced evaporation over the Atlantic basin in future climates, but for a moderate increase in radiative forcing (B1 and 2 CO2 scenarios), there is a decrease of the fresh water flux carried by the MOC into the Atlantic (the deficit is made up by increased fresh water transport by the gyre circulation). In this forcing regime the salt advection feedback becomes less negative: for three models from an ensemble of eight it is positive in a 2 CO2 climate, while two models feature a positive feedback in the pre-industrial climate. For even warmer climates (A1B-equilibrium and 4 CO2) the salt feedback becomes more negative (damping) again. It is shown that the decrease in northward fresh water transport at 34°S by the MOC (in B1-equilibrium and 2 CO2) is due to a reduction of the inflow of intermediate waters relative to thermocline waters, associated with a robust shoaling of the MOC in future, warmer climates. In A1B and 4 CO2 climates northward freshwater transport increases again. The MOC keeps shoaling, but both intermediate and thermocline water masses freshen. 相似文献
20.
Ocean heat transport into the Arctic in the twentieth and twenty-first century in EC-Earth 总被引:1,自引:1,他引:0
The ocean heat transport into the Arctic and the heat budget of the Barents Sea are analyzed in an ensemble of historical and future climate simulations performed with the global coupled climate model EC-Earth. The zonally integrated northward heat flux in the ocean at 70°N is strongly enhanced and compensates for a reduction of its atmospheric counterpart in the twenty first century. Although an increase in the northward heat transport occurs through all of Fram Strait, Canadian Archipelago, Bering Strait and Barents Sea Opening, it is the latter which dominates the increase in ocean heat transport into the Arctic. Increased temperature of the northward transported Atlantic water masses are the main reason for the enhancement of the ocean heat transport. The natural variability in the heat transport into the Barents Sea is caused to the same extent by variations in temperature and volume transport. Large ocean heat transports lead to reduced ice and higher atmospheric temperature in the Barents Sea area and are related to the positive phase of the North Atlantic Oscillation. The net ocean heat transport into the Barents Sea grows until about year 2050. Thereafter, both heat and volume fluxes out of the Barents Sea through the section between Franz Josef Land and Novaya Zemlya are strongly enhanced and compensate for all further increase in the inflow through the Barents Sea Opening. Most of the heat transported by the ocean into the Barents Sea is passed to the atmosphere and contributes to warming of the atmosphere and Arctic temperature amplification. Latent and sensible heat fluxes are enhanced. Net surface long-wave and solar radiation are enhanced upward and downward, respectively and are almost compensating each other. We find that the changes in the surface heat fluxes are mainly caused by the vanishing sea ice in the twenty first century. The increasing ocean heat transport leads to enhanced bottom ice melt and to an extension of the area with bottom ice melt further northward. However, no indication for a substantial impact of the increased heat transport on ice melt in the Central Arctic is found. Most of the heat that is not passed to the atmosphere in the Barents Sea is stored in the Arctic intermediate layer of Atlantic water, which is increasingly pronounced in the twenty first century. 相似文献