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1.
K. Halimeda Kilbourne Terrence M. Quinn Thomas P. Guilderson Robert S. Webb Frederick W. Taylor 《Climate Dynamics》2007,29(1):51-62
Water that forms the Florida Current, and eventually the Gulf Stream, coalesces in the Caribbean from both subtropical and
equatorial sources. The equatorial sources are made up of, in part, South Atlantic water moving northward and compensating
for southward flow at depth related to meridional overturning circulation. Subtropical surface water contains relatively high
amounts of radiocarbon (14C), whereas equatorial waters are influenced by the upwelling of low 14C water and have relatively low concentrations of 14C. We use a 250 year record of Δ14C in a coral from southwestern Puerto Rico along with previously published coral Δ14C records as tracers of subtropical and equatorial water mixing in the northern Caribbean. Data generated in this study and
from other studies indicate that the influence of either of the two water masses can change considerably on interannual to
interdecadal time scales. Variability due to ocean dynamics in this region is large relative to variability caused by atmospheric
14C changes, thus masking the Suess effect at this site. A mixing model produced using coral Δ14C illustrates the time varying proportion of equatorial versus subtropical waters in the northern Caribbean between 1963 and
1983. The results of the model are consistent with linkages between multidecadal thermal variability in the North Atlantic
and meridional overturning circulation. Ekman transport changes related to tradewind variability are proposed as a possible
mechanism to explain the observed switches between relatively low and high Δ14C values in the coral radiocarbon records. 相似文献
2.
Responses of global ocean circulation and temperature to freshwater runoff from major rivers were studied by blocking regional runoff in the global ocean general circulation model(OGCM)developed at the Massachusetts Institute of Technology.Runoff into the tropical Atlantic,the western North Pacific,and the Bay of Bengal and northern Arabian Sea were selectively blocked.The blocking of river runoff first resulted in a salinity increase near the river mouths(2 practical salinity units).The saltier and,therefore,denser water was then transported to higher latitudes in the North Atlantic,North Pacific,and southern Indian Ocean by the mean currents.The subsequent density contrasts between northern and southern hemispheric oceans resulted in changes in major ocean currents.These anomalous ocean currents lead to significant temperature changes(1°C-2°C)by the resulting anomalous heat transports.The current and temperature anomalies created by the blocked river runoff propagated from one ocean basin to others via coastal and equatorial Kelvin waves.This study suggests that river runoff may be playing an important role in oceanic salinity,temperature,and circulations;and that partially or fully blocking major rivers to divert freshwater for societal purposes might significantly change ocean salinity,circulations,temperature,and atmospheric climate.Further studies are necessary to assess the role of river runoff in the coupled atmosphere-ocean system. 相似文献
3.
The results from an integration of a global ocean circulation model have been condensed into an analysis of the volume, heat, and salt transports among the major ocean basins. Transports are also broken down between the model's Ekman, thermocline, and deep layers. Overall, the model does well. Horizontal exchanges of mass, heat, and salt between ocean basins have reasonable values; and the volume of North Atlantic Deep Water (NADW) transport is in general agreement with what limited observations exist. On a global basis the zonally integrated meridional heat transport is poleward at all latitudes except for the latitude band 30°S to 45°S. This anomalous transport is most likely a signature of the model's inability to form Antarctic Intermediate (AAIW) and Antarctic bottom water (AABW) properly. Eddy heat transport is strong at the equator where its convergence heats the equatorial Pacific about twice as much as it heats the equatorial Atlantic. The greater heating in the Pacific suggests that mesoscale eddies may be a vital mechanism for warming and maintaining an upwelling portion of the global conveyor-belt circulation. The model's fresh water transport compares well with observations. However, in the Atlantic there is an excessive southward transport of fresh water due to the absence of the Mediterranean outflow and weak northward flow of AAIW. Eddies in the mid-latitudes act to redistribute heat and salt down the mean gradients. Residual fluxes calculated from a sum of the computed advective (including eddies), forced, and stored fluxes of heat and salt represent transport mostly due to vertical sub-grid scale mixing processes. Perhaps the model's greatest weakness is the lack of strong AAIW and AABW circulation cells. Accurate thermohaline forcing in the North Atlantic (based on numerous hydrographic observations) helps the model adequately produce NADW. In contrast, the southern ocean is an area of sparse observation. Better thermohaline observations in this area may be needed if models such as this are to produce the deep convection that will achieve more accurate simulations of the global 3-dimensional circulation. 相似文献
4.
The Gulf Stream, one of the strongest currents in the world, transports approximately 31 Sv of water (Kelly and Gille, 1990, Baringer and Larsen, 2001, Leaman et al., 1995) and 1.3 × 1015 W (Larsen, 1992) of heat into the Atlantic Ocean, and warms the vast European continent. Thus any change of the Gulf Stream could lead to the climate change in the European continent, and even worldwide (Bryden et al., 2005). Past studies have revealed a diminished Gulf Stream and oceanic heat transport that was possibly associated with a southward migration of intertropical convergence zone (ITCZ) and may have contributed to Little Ice Age (AD ∼1200 to 1850) in the North Atlantic (Lund et al., 2006). However, the causations of the Gulf Stream weakening due to the southward migration of the ITCZ remain uncertain. Here we use satellite observation data and employ a model (oceanic general circulation model – OGCM) to demonstrate that the Brazilian promontory in the east coast of South America may have played a crucial role in allocating the equatorial currents, while the mean position of the equatorial currents migrates between northern and southern hemisphere in the Atlantic Ocean. Northward migrations of the equatorial currents in the Atlantic Ocean have little influence on the Gulf Stream. Nevertheless, southward migrations, especially abrupt large southward migrations of the equatorial currents, can lead to the increase of the Brazil Current and the significant decrease of the North Brazil Current, in turn the weakening of the Gulf Stream. The results from the model simulations suggest the mean position of the equatorial currents in the Atlantic Ocean shifted at least 180–260 km southwards of its present-day position during the Little Ice Age based on the calculations of simple linear equations and the OGCM simulations. 相似文献
5.
We use a coarse resolution ocean general circulation model to study the relation between meridional pressure and density gradients in the Southern Ocean and North Atlantic and the Atlantic meridional overturning circulation. In several experiments, we artificially modify the meridional density gradients by applying different magnitudes of the Gent–McWilliams isopycnal eddy diffusion coefficients in the Southern Ocean and in the North Atlantic and investigate the response of the simulated Atlantic meridional overturning to such changes. The simulations are carried out close to the limit of no diapycnal mixing, with a very small explicit vertical diffusivity and a tracer advection scheme with very low implicit diffusivities. Our results reveal that changes in eddy diffusivities in the North Atlantic affect the maximum of the Atlantic meridional overturning, but not the outflow of North Atlantic Deep Water into the Southern Ocean. In contrast, changes in eddy diffusivities in the Southern Ocean affect both the South Atlantic outflow of North Atlantic Deep Water and the maximum of the Atlantic meridional overturning. Results from these experiments are used to investigate the relation between meridional pressure gradients and the components of the Atlantic meridional overturning. Pressure gradients and overturning are found to be linearly related. We show that, in our simulations, zonally averaged deep pressure gradients are very weak between 20°S and about 30°N and that between 30°N and 60°N the zonally averaged pressure grows approximately linearly with latitude. This pressure difference balances a westward geostrophic flow at 30–40°N that feeds the southbound deep Atlantic western boundary current. We extend our analysis to a large variety of experiments in which surface freshwater forcing, vertical mixing and winds are modified. In all experiments, the pycnocline depth, assumed to be the relevant vertical scale for the northward volume transport in the Atlantic, is found to be approximately constant, at least within the coarse vertical resolution of the model. The model behaviour hence cannot directly be related to conceptual models in which changes in the pycnocline depth determine the strength of Atlantic meridional flow, and seems conceptually closer to Stommel’s box model. In all our simulations, the Atlantic overturning seems to be mainly driven by Southern Ocean westerlies. However, the actual strength of the Atlantic meridional overturning is not determined solely by the Southern Ocean wind stress but as well by the density/pressure gradients created between the deep water formation regions in the North Atlantic and the inflow/outflow region in the South Atlantic. 相似文献
6.
The ocean response to surface temperature transients is simulated with the use of the Hamburg large-scale geostrophic (LSG)
ocean general circulation model (OGCM). The transition, from the present to a climate corresponding to a doubling of the atmospheric
CO2 content, is compared with the reversed transition. For the Atlantic, the time scale for the deep ocean to adjust to the temperature
changes was similar for both transitions. In the Pacific, the time scale is shorter for the present to warm transition than
for the reverse case, a result of increased production of Antarctic bottom water (AABW) during the warm climate. While the
transition from cold to warm climate shows no secular variability, the reversed transition generates considerable variability
on time scales of 300–400 years. For the warm climate, oscillations with periods of 45 years are found in the Southern Ocean.
Results of principal oscillation pattern (POP) analysis indicate that these oscillations are due to interaction between convection
in the Southern Ocean and advected salinity anomalies in the Antarctic Circumpolar Current (ACC) and the Southern Pacific
Ocean.
Received: 19 September 1995 / Accepted: 15 March 1996 相似文献
7.
C. J. C. Reason 《Meteorology and Atmospheric Physics》1996,58(1-4):51-63
Summary The sensitivity of the circulation and water mass properties in a global ocean circulation model (OGCM) to the stability dependent vertical mixing parameterisations of Pacanowski and Philander (1981) and Henderson-Sellers (1985) is investigated. The work extends a previous study which examined upper ocean charateristics and mixed layer evolution resulting from these schemes incorporated in the OGCM and made a recommendation as to the appropriateness of the latter scheme for global models. Under the assumption of constant vertical eddy coefficients (the control case), the model climatology displays acceptable values of North Atlantic Deep Water formation, Antarctic Circumpolar Current strength, and Indonesian throughflow but an excessively deep and diffuse pycnocline structure with weak stratification in the deep ocean. It is found that these circulation and water mass properties are sensitive to the choice of parametrisation of vertical mixing and that the two stability dependent schemes are unable to perform satisfactorily over the global domain, instead being better suited to the tropics. Under conditions optimal for representing the tropical current and temperature structure, these schemes result in significant weakening of major currents (particularly, the ACC) and reductions in the rates of deep water formation and poleward heat transports. These deficiencies can only be remedied at the expense of the improvements to the simulation in the tropical part of the domain. The results presented indicate that the suggestions made in the previous study do not extend to situations where the deep ocean, and particularly, the global thermohaline circulation is important.With 8 Figures 相似文献
8.
This work concerns an analysis of inter-basin and inter-layer exchanges in the component ocean part of the coupled ECHAM4/OPYC3
general circulation model, aimed at documenting the simulation of North Atlantic Deep Water (NADW) and related thermohaline
circulations in the Indian and Pacific Oceans. The modeled NADW is formed mainly in the Greenland– Iceland–Norwegian Seas
through a composite effect of deep convection and downward cross-isopycnal transport. The modeled deep-layer outflow of NADW
can reach 16 Sv near 30 °S in the South Atlantic, with the corresponding upper-layer return flow mainly coming from the “cold
water path” through Drake Passage. Less than 4 Sv of the Agulhas “leakage” water contributes to the replacement of NADW along
the “warm water path”. In the South Atlantic Ocean, the model shows that some intermediate isopycnal layers with potential
densities ranging between 27.0 and 27.5 are the major water source that compensate the NADW return flow and enhance the Circumpolar
Deep Water (CDW) flowing from the Atlantic into Indian Ocean. The modeled thermohaline circulations in the Indian and Pacific
Oceans indicate that the Indian Ocean may play the major role in converting deep water into intermediate water. About 16 Sv
of the CDW-originating deep water enters the Indian Ocean northward of 31 °S, of which more than 13 Sv “upwell” mainly near
the continental boundaries of Africa, South Asia and Australia through inter-layer exchanges and return to the Antarctic Circumpolar
Current (ACC) as intermediate-layer water. As a contrast, only 4 Sv of Pacific intermediate water is connected to “upwelling”
flow southward across 31 °S while the magnitude of northward deep flow across 31 °S in the Pacific Ocean is significantly
greater than that in the Indian Ocean. The model suggests that a large portion of the deep waters entering the Pacific Ocean
(about 14 Sv) “upwells” continually into some upper layers through the thermocline, and becomes the source of the Indonesian
throughflow. Uncertainties in these results may be related to the incomplete adjustment of the model’s isopycnal layers and
the sensitivity of the Indonesian throughflow to the model’s geography and topography.
Received: 12 August 1997/Accepted: 12 March 1998 相似文献
9.
海洋环流模式模拟自然
和核辐射14C的分布 总被引:9,自引:1,他引:8
放射性14C在海洋环流研究和人为CO2问题的研究中都有重要地位。本文用海洋环流模式模拟了海洋中自然14C的分布及海洋对核辐射产生的放射性14C的吸收, 以期对海洋吸收人为CO2的能力做一初步的研究。模拟的海洋环流结果与观测相比符合得较好,成功地模拟出了北大西洋深水(NADW)、南极底水 (AABW)等基本特征。对自然14C的模拟揭示出了海洋通风的基本特征。模拟出的沿GEOSECS 路径的南、北垂直截面与观测结果符合得较好。对核辐射14C的模拟表明:模式模拟的沿GEOSECS 路径的南、北垂直截面与观测结果符合得较好;模拟出的海洋表面核辐射浓度与观测值一致,但核辐射14C在海洋中的柱存量和平均穿透深度都比观测结果要小。文中分析了造成这种差异的可能原因。 相似文献
10.
Fundamental framework and experiments of the third generation of IAP / LASG world ocean general circulation model 总被引:36,自引:8,他引:28
A new generation of the IAP / LASG world ocean general circulation model is designed and presented based on the previous 20-layer model, with enhanced spatial resolutions and improved parameterizations. The model uses a triangular-truncated spectral horizontal grid system with its zonal wave number of 63 (T63) to match its atmospheric counterpart of a T63 spectral atmosphere general circulation model in a planned coupled ocean-atmosphere system. There are 30 layers in vertical direction, of which 20 layers are located above 1000 m for better depicting the permanent thermocline. As previous ocean models developed in IAP / LASG, a free surface (rather than “rigid-lid” approximation) is included in this model. Compared with the 20-layer model, some more detailed physical parameterizations are considered, including the along / cross isopycnal mixing scheme adapted from the Gent-MacWilliams scheme. The model is spun up from a motionless state. Initial conditions for temperature and salinity are taken from the three-dimensional distributions of Levitus’ annual mean observation. A preliminary analysis of the first 1000-year integration of a control experiment shows some encouraging improvements compared with the twenty-layer model, particularly in the simulations of permanent thermocline, thermohaline circu?lation, meridional heat transport, etc. resulted mainly from using the isopycnal mixing scheme. However, the use of isopycnal mixing scheme does not significantly improve the simulated equatorial thermocline. A series of numerical experiments show that the most important contribution to the improvement of equatori?al thermocline and the associated equatorial under current comes from reducing horizontal viscosity in the equatorial regions. It is found that reducing the horizontal viscosity in the equatorial Atlantic Ocean may slightly weaken the overturning rate of North Atlantic Deep Water. 相似文献
11.
O. A. Tarasova C. A. M. Brenninkmeijer S. S. Assonov N. F. Elansky T. Röckmann M. A. Sofiev 《Journal of Atmospheric Chemistry》2007,57(2):135-152
The concentration, radiocarbon (14C) and stable isotope (13C and 18O) content of CO have been determined in air samples collected across Russia (about 8,500 km) and along the Ob river during
the summer of 1999 to study the CO sources and sinks. An instrumented carriage on the Trans-Siberian railway and a boat on
the river Ob were used as atmospheric measurement platforms. In general, CO mixing ratios, CO stable isotope ratios, as well
as the abundances of 14CO over West Siberia were similar to those found at remote northern hemispheric baseline monitoring stations. Identified sources
of CO along the Ob appear to be connected to methane oxidation based on an inferred δ13Csource = −36.8 ± 0.6‰, while the value for δ18Osource = 9.0 ± 1.6‰ identifies it as burning. Thus flaring in the oil and gas production can be supposed to be a source. The extreme
13C depletion and concomitant 18O enrichment for two of the boat samples unambiguously indicates contamination by CO from combustion of natural gas (inferred
values δ13Csource = −40.3‰ and δ18Osource = 17.5‰). For these two samples, that have strongly elevated 14CO concentrations, the industrial area near Tomsk is identified as a source area using meteorological calculations. Along
the Trans-Siberian Railroad background CO was to various degrees contaminated with CO from methane combustion (δ13Csource = −35.7 ± 6.2‰ and δ18Osource = 10.3 ± 1.8‰). The impact of industrial burning was discernable in the vicinity of Perm-Kungur. 相似文献
12.
Reindert J. Haarsma Edmo J. D. Campos Sybren Drijfhout Wilco Hazeleger Camiel Severijns 《Climate Dynamics》2011,36(5-6):989-1003
In this paper we use a coupled ocean?Catmosphere model to investigate the impact of the interruption of Agulhas leakage of Indian ocean water on the tropical Atlantic, a region where strong coupled ocean?Catmosphere interactions occur. The effect of a shut down of leakage of Indian ocean water is isolated from the effect of a collapse of the MOC. In our experiments, the ocean model is forced with boundary conditions in the southeastern corner of the domain that correspond to no interocean exchange of Indian ocean water into the Atlantic. The southern boundary condition is taken from the Levitus data and ensures an MOC in the Atlantic. Within this configuration, instead of warm and salty Indian ocean water temperature (cold) and salinity (fresh) anomalies of southern ocean origin propagate into the South Atlantic and eventually reach the equatorial region, mainly in the thermocline. This set up mimics the closure of the ??warm water path?? in favor of the ??cold water path??. As part of the atmospheric response, there is a northward shift of the intertropical convergence zone (ITCZ). The changes in trade winds lead to reduced Ekman pumping in the equatorial region. This leads to a freshening and warming of the surface waters along the equator. Especially in the Cold Tongue region, the cold and fresh subsurface anomalies do not reach the surface due to the reduced upwelling. The anomaly signals are transported by the equatorial undercurrent and spread away from the equator within the thermocline. Part of the anomaly eventually reaches the Tropical North Atlantic, where it affects the Guinea Dome. Surprisingly, the main effect at the surface is small on the equator and relatively large at the Guinea Dome. In the atmosphere, the northward shift of the ITCZ is associated with a band of negative precipitation anomalies and higher salinities over the Tropical South Atlantic. An important implication of these results is that the modified water characteristics due to a shut down of the Agulhas leakage remain largely unaffected when crossing the equatorial Atlantic and therefore can affect the deepwater formation in the North Atlantic. This supports the hypothesis that the Agulhas leakage is an important source region for climate change and decadal variability of the Atlantic. 相似文献
13.
The sensitivity of tropical Atlantic climate to upper ocean mixing is investigated using an ocean-only model and a coupled
ocean–atmosphere model. The upper ocean thermal structure and associated atmospheric circulation prove to be strongly related
to the strength of upper ocean mixing. Using the heat balance in the mixed layer it is shown that an excessively cold equatorial
cold tongue can be attributed to entrainment flux at the base of the oceanic mixed layer, that is too large. Enhanced entrainment
efficiency acts to deepen the mixed layer and causes strong reduction in the upper ocean divergence in the central equatorial
Atlantic. As a result, the simulated sea surface temperature, thermocline structure, and upwelling velocities are close to
the observed estimates. In the coupled model, the seasonal migration of the Intertropical Convergence Zone (ITCZ) reduces
when the entrainment efficiency in the oceanic mixed layer is enhanced. The precipitation rates decrease in the equatorial
region and increase along 10°N, resulting in a more realistic Atlantic Marine ITCZ. The reduced meridional surface temperature
gradient in the eastern tropical Atlantic prohibits the development of convective precipitation in the southeastern part of
the tropical Atlantic. Also, the simulation of tropical Atlantic variability as expressed in the meridional gradient mode
and the eastern cold tongue mode improves when the entrainment efficiency is enhanced. 相似文献
14.
A coarse-grid global ocean general circulation model (OGCM) is used to determine the role of sub-grid scale eddy parametrization
schemes in the response to idealized changes in the surface heat flux, of the same order as expected under increased atmospheric
CO2 concentrations. Two schemes are employed. The first (H) incorporates standard horizontal mixing, whereas the second (G) combines
both enhanced isopycnal mixing and eddy-induced transport. Uniform surface heating anomalies of +2 W m-2 and −2 W m-2 are applied for 50 years, and the results are compared with a control experiment in which no anomalous heating is imposed.
A passive “heat” tracer is applied uniformly (at a rate of 2 W m-2 for 50 years) in a separate experiment. The sea-surface temperature response to global surface heating is generally larger
in G, especially in the northern subtropical gyres, along the southern coast of Australia and off the Antarctic coast. A pronounced
interhemispheric asymmetry (primarily arising from an anomalous response south of 35 °S) is evident in both H and G. The surface
trapping of passive tracers in the Southern Hemisphere is generally greater in G than it is in H, and is particularly pronounced
along the prime meridian (0 °E). Dynamical changes (i.e., changes in horizontal and vertical currents, convection, and preferred
mixing and eddy transport pathways) enhance surface warming in the tropics and subtropics in both G and H. They are dominated
by an anomalous meridional overturning centred on the equator, which may also operate in greenhouse warming experiments using
coupled atmosphere-ocean GCMs. Over the Southern Ocean the passive tracer experiments and associated ventilation rates suggest
that surface warming will be greater in G than in H. In fact, the contrast between the dynamical responses evident in G and
H in the actual heating experiments leads to a situation in which the reverse is often true. Overall, dynamical changes enhance
the interhemispheric assymetry, more so in G than in H.
Received: August 1996/Accepted: 20 March 1997 相似文献
15.
Modelling the concentration of atmospheric CO2 during the Younger Dryas climate event 总被引:1,自引:0,他引:1
O. Marchal T. F. Stocker F. Joos A. Indermühle T. Blunier J. Tschumi 《Climate Dynamics》1999,15(5):341-354
The Younger Dryas (YD, dated between 12.7–11.6 ky BP in the GRIP ice core, Central Greenland) is a distinct cold period in
the North Atlantic region during the last deglaciation. A popular, but controversial hypothesis to explain the cooling is
a reduction of the Atlantic thermohaline circulation (THC) and associated northward heat flux as triggered by glacial meltwater.
Recently, a CH4-based synchronization of GRIP δ18O and Byrd CO2 records (West Antarctica) indicated that the concentration of atmospheric CO2 (COatm
2) rose steadily during the YD, suggesting a minor influence of the THC on COatm
2 at that time. Here we show that the COatm
2 change in a zonally averaged, circulation-biogeochemistry ocean model when THC is collapsed by freshwater flux anomaly is
consistent with the Byrd record. Cooling in the North Atlantic has a small effect on COatm
2 in this model, because it is spatially limited and compensated by far-field changes such as a warming in the Southern Ocean.
The modelled Southern Ocean warming is in agreement with the anti-phase evolution of isotopic temperature records from GRIP
(Northern Hemisphere) and from Byrd and Vostok (East Antarctica) during the YD. δ13C depletion and PO4 enrichment are predicted at depth in the North Atlantic, but not in the Southern Ocean. This could explain a part of the
controversy about the intensity of the THC during the YD. Potential weaknesses in our interpretation of the Byrd CO2 record in terms of THC changes are discussed.
Received: 27 May 1998 / Accepted: 5 November 1998 相似文献
16.
T. M. Lenton M. S. Williamson N. R. Edwards R. Marsh A. R. Price A. J. Ridgwell J. G. Shepherd S. J. Cox 《Climate Dynamics》2006,26(7-8):687-711
A new Earth system model, GENIE-1, is presented which comprises a 3-D frictional geostrophic ocean, phosphate-restoring marine biogeochemistry, dynamic and thermodynamic sea-ice, land surface physics and carbon cycling, and a seasonal 2-D energy-moisture balance atmosphere. Three sets of model climate parameters are used to explore the robustness of the results and for traceability to earlier work. The model versions have climate sensitivity of 2.8–3.3°C and predict atmospheric CO2 close to present observations. Six idealized total fossil fuel CO2 emissions scenarios are used to explore a range of 1,100–15,000 GtC total emissions and the effect of rate of emissions. Atmospheric CO2 approaches equilibrium in year 3000 at 420–5,660 ppmv, giving 1.5–12.5°C global warming. The ocean is a robust carbon sink of up to 6.5 GtC year−1. Under ‘business as usual’, the land becomes a carbon source around year 2100 which peaks at up to 2.5 GtC year−1. Soil carbon is lost globally, boreal vegetation generally increases, whilst under extreme forcing, dieback of some tropical and sub-tropical vegetation occurs. Average ocean surface pH drops by up to 1.15 units. A Greenland ice sheet melt threshold of 2.6°C local warming is only briefly exceeded if total emissions are limited to 1,100 GtC, whilst 15,000 GtC emissions cause complete Greenland melt by year 3000, contributing 7 m to sea level rise. Total sea-level rise, including thermal expansion, is 0.4–10 m in year 3000 and ongoing. The Atlantic meridional overturning circulation shuts down in two out of three model versions, but only under extreme emissions including exotic fossil fuel resources. 相似文献
17.
D. J. Bernie E. Guilyardi G. Madec J. M. Slingo S. J. Woolnough 《Climate Dynamics》2007,29(6):575-590
The diurnal cycle is a fundamental time scale in the climate system, at which the upper ocean and atmosphere are routinely
observed to vary. Current climate models, however, are not configured to resolve the diurnal cycle in the upper ocean or the
interaction of the ocean and atmosphere on these time scales. This study examines the diurnal cycle of the tropical upper
ocean and its climate impacts. In the present paper, the first of two, a high vertical resolution ocean general circulation
model (OGCM), with modified physics, is developed which is able to resolve the diurnal cycle of sea surface temperature (SST)
and current variability in the upper ocean. It is then validated against a satellite derived parameterization of diurnal SST
variability and in-situ current observations. The model is then used to assess rectification of the intraseasonal SST response
to the Madden–Julian oscillation (MJO) by the diurnal cycle of SST. Across the equatorial Indo-Pacific it is found that the
diurnal cycle increases the intraseasonal SST response to the MJO by around 20%. In the Pacific, the diurnal cycle also modifies
the exchange of momentum between equatorially divergent Ekman currents and the meridionally convergent geostrophic currents
beneath, resulting in a 10% increase in the strength of the Ekman cells and equatorial upwelling. How the thermodynamic and
dynamical impacts of the diurnal cycle effect the mean state, and variability, of the climate system cannot be fully investigated
in the constrained design of ocean-only experiments presented here. The second part of this study, published separately, addresses
the climate impacts of the diurnal cycle in the coupled system by coupling the OGCM developed here to an atmosphere general
circulation model. 相似文献
18.
A three-dimensional ocean carbon cycle model which is a general circulation model coupled with simple biogeochemical processes is used to simulate CO2 uptake by the ocean.The OGCM used is a modified version of the Geophysical Fluid Dynamics Laboratory modular ocean model(MOM2).The ocean chemistry and a simple ocean biota model are included.Principal variablesare total CO2,alkalinity and phosphate.The vertical profile of POC flux observed by sediment traps is adopted,the rain ratio,a ratio of production rate of calcite against that of POC,and the bio-production efficiency should be 0.06 and 2 per year,separately.The uptake of anthropogenic CO2 by the ocean is studied.Calculated oceanic uptake of anthropogenic CO2 during the 1980s is 2.05×1015g(Pg)per year.The regional distributions of global oceanic CO2 are discussed. 相似文献
19.
Rong-Hua Zhang 《Climate Dynamics》2014,42(1-2):467-485
Tropical instability waves (TIWs) arise from oceanic instability in the eastern tropical Pacific and Atlantic Oceans, having a clear atmospheric signature that results in coupled atmosphere–ocean interactions at TIW scales. In this study, the extent to which TIW-induced surface wind feedback influences the ocean is examined using an ocean general circulation model (OGCM). The TIW-induced wind stress (τTIW) part is diagnostically determined using an empirical τTIW model from sea surface temperature (SST) fields simulated in the OGCM. The interactively represented TIW wind tends to reduce TIW activity in the ocean and influence the mean state, with largest impacts during TIW active periods in fall and winter. In December, the interactive τTIW forcing induces a surface cooling (an order of ?0.1 to ?0.3 °C), an increased heat flux into the ocean, a shallower mixed layer and a weakening of the South Equatorial Current in the eastern equatorial Pacific. Additionally, the TIW wind effect yields a pronounced latitudinal asymmetry of sea level field across the equator, and a change to upper thermal structure, characterized by a surface cooling and a warming below in the thermocline, leading to a decreased temperature gradient between the mixed layer and the thermocline. Processes responsible for the τTIW–induced cooling effects are analyzed. Vertical mixing and meridional advection are the two terms in the SST budget that are dominantly affected by the TIW wind feedback: the cooling effect from the vertical mixing on SST is enhanced, with the maximum induced cooling in winter; the warming effect from the meridional advection is reduced in July–October, but enhanced in November–December. Additional experiments are performed to separate the relative roles the affected surface momentum and heat fluxes play in the cooling effect on SST. This ocean-only modeling work indicates that the effect of TIW-induced wind feedback is small but not negligible, and may need to be adequately taken into account in large-scale climate modeling. 相似文献
20.
An ocean general circulation model of global domain, full continental geometry and bottom topography, is used to study the influence of the Bering Strait on the general circulation by comparing equilibrium solutions obtained with and without a land-bridge between Siberia and Alaska. The model is integrated with restoring boundary conditions (BC) on temperature and salinity, and later, with mixed BC in which a restoring BC on temperature is maintained but a specified flux condition on salinity is imposed. In both cases, the effect of the Bering Strait is to allow a flow of about 1.25–1.5 Sv from the North Pacific to the Arctic Ocean and, ultimately, back to the North Pacific along the western boundary current regions of the Atlantic and Indian Oceans. When a restoring BC on salinity is used, the overturning associated with North Atlantic Deep Water and Antarctic Intermediate Water formation are increased if the Bering Strait is present in the model geometry. The result of switching to a specified flux BC on salinity is to cause a transition in the THC in which the overturning associated with North Atlantic Deep Water formation increases from about 12 Sv to about 22 Sv. This transition occurs in an essentially smooth fashion with no significant variability and is about 12% smaller in magnitude if the Bering Strait is present in the model geometry. Because the Bering Strait appears to exert some influence on the general circulation and the formation of deep water masses, it is recommended that this Strait be included in the geometry of similar resolution models designed to study the deep ocean and potential changes in climate.
Correspondence to: CJC Reason 相似文献