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1.
Summary “Koshava” is a gusty wind of changeable intensity, blowing from a south-easterly direction, over Serbia, Romania and Bulgaria.
It is caused by the interaction between the synoptic circulation and the orography of the Carpathian and the Balkan mountains.
This paper analyzes wind data measured at the Belgrade-Observatory during the longest period of consecutive days of “Koshava”
which occurred from 14 January to 13 February 1972. Mean hourly wind speed data has been examined using spectral analysis.
The power spectra are calculated using autocorrelation spectral analysis, the multi-taper method and wavelet transform. The
maximum of which is about 122 h (5 days) corresponds to the time span of synoptic processes. 相似文献
2.
Simon F. B. Tett Richard Betts Thomas J. Crowley Jonathan Gregory Timothy C. Johns Andy Jones Timothy J. Osborn Elisabeth Öström David L. Roberts Margaret J. Woodage 《Climate Dynamics》2007,28(1):3-34
A climate simulation of an ocean/atmosphere general circulation model driven with natural forcings alone (constant “pre-industrial” land-cover and well-mixed greenhouse gases, changing orbital, solar and volcanic forcing) has been carried out from 1492 to 2000. Another simulation driven with natural and anthropogenic forcings (changes in greenhouse gases, ozone, the direct and first indirect effect of anthropogenic sulphate aerosol and land-cover) from 1750 to 2000 has also been carried out. These simulations suggest that since 1550, in the absence of anthropogenic forcings, climate would have warmed by about 0.1 K. Simulated response is not in equilibrium with the external forcings suggesting that both climate sensitivity and the rate at which the ocean takes up heat determine the magnitude of the response to forcings since 1550. In the simulation with natural forcings climate sensitivity is similar to other simulations of HadCM3 driven with CO2 alone. Climate sensitivity increases when anthropogenic forcings are included. The natural forcing used in our experiment increases decadal–centennial time-scale and large spatial scale climate variability, relative to internal variability, as diagnosed from a control simulation. Mean conditions in the natural simulation are cooler than in our control simulation reflecting the reduction in forcing. However, over certain regions there is significant warming, relative to control, due to an increase in forest cover. Comparing the simulation driven by anthropogenic and natural forcings with the natural-only simulation suggests that anthropogenic forcings have had a significant impact on, particularly tropical, climate since the early nineteenth century. Thus the entire instrumental temperature record may be “contaminated” by anthropogenic influences. Both the hydrological cycle and cryosphere are also affected by anthropogenic forcings. Changes in tree-cover appear to be responsible for some of the local and hydrological changes as well as an increase in northern hemisphere spring snow cover.
相似文献
| Simon F. B. TettEmail: |
3.
The concept of radiative forcing has been extensively used as an indicator of the potential importance of climate change
mechanisms. It allows a first order estimate of the global-mean surface temperature change; and it is possible to compare
forcings from different mechanisms, on the assumption that similar global-mean forcings produce similar global-mean surface
temperature changes. This study illustrates two circumstances where simple models show that the conventional definition of
radiative forcing needs refining. These problems arise mainly with the calculation of forcing due to stratospheric ozone depletion.
The first part uses simple arguments to produce an alternative definition of radiative forcing, using a time-dependent stratospheric
adjustment method, which can give different forcings from those calculated using the standard definition. A seasonally varying
ozone depletion can produce a quite different seasonal evolution of forcing than fixed dynamical heating arguments would suggest.
This is especially true of an idealised and extreme “Antarctic ozone hole” type scenario where a sudden loss of ozone is followed
by a sudden recovery. However, for observed ozone changes the annually averaged forcing is usually within 5% of the forcing
calculated using the fixed dynamical heating approximation. Another problem with the accepted view of radiative forcing arises
from the definition of the tropopause considered in the second part of this study. For a correct radiative forcing estimate
the “tropopause” needs to separate the atmosphere into regions with a purely radiative response and those with a radiative-convective
response. From radiative-convective model results it is found that radiative equilibrium conditions persist for several kilometres
below the tropopause (the tropopause being defined as where the lapse rate reaches 2 K km-1). This region needs to be included in stratospheric adjustment calculations for an accurate calculation of forcing, as it
is only the region between the surface and the top of the convection that can be considered as a single, forced, system. Including
temperature changes in this region has a very large effect on stratospheric ozone forcing estimates, and can reduce the magnitude
of the forcing by more than a factor of two. Although these experiments are performed using simple climate models, the results
are of equal importance for the analysis of forcing-response relationships using general circulation models.
Received: 25 October 1996/Accepted: 14 April 1997 相似文献
4.
A multi-model ensemble approach for assessment of climate change impact on surface winds in France 总被引:2,自引:1,他引:1
Statistical downscaling of 14 coupled atmosphere-ocean general circulation models (AOGCM) is presented to assess potential
changes of the 10 m wind speeds in France. First, a statistical downscaling method is introduced to estimate daily mean 10 m
wind speed at specific sites using general circulation model output. Daily 850 hPa wind field has been selected as the large
scale circulation predictor. The method is based on a classification of the daily wind fields into a few synoptic weather
types and multiple linear regressions. Years are divided into an extended winter season from October to March and an extended
summer season from April to September, and the procedure is conducted separately for each season. ERA40 reanalysis and observed
station data have been used to build and validate the downscaling algorithm over France for the period 1974–2002. The method
is then applied to 14 AOGCMs of the coupled model intercomparison project phase 3 (CMIP3) multi-model dataset. Three time
periods are focused on: a historical period (1971–2000) from the climate of the twentieth century experiment and two climate
projection periods (2046–2065 and 2081–2100) from the IPCC SRES A1B experiment. Evolution of the 10 m wind speed in France
and associated uncertainties are discussed. Significant changes are depicted, in particular a decrease of the wind speed in
the Mediterranean area. Sources of those changes are investigated by quantifying the effects of changes in the weather type
occurrences, and modifications of the distribution of the days within the weather types. 相似文献
5.
Arun Chakraborty H. C. Upadhyaya O. P. Sharma Divya Jaisawal S. K. Deb 《Meteorology and Atmospheric Physics》2003,83(3-4):197-220
Summary ?A three-dimensional Ocean General Circulation Model has been developed in stretched coordinate from scratch. The same model
has been used to perform some numerical experiments to simulate the basic circulation pattern and the model variability to
atmospheric forcing. For numerical simulations 72 × 25 grid points in the horizontal directions and nine (10, 30, 75, 250,
500, 1000, 1500, 2000 and 3000 m) vertical levels are considered. The lateral boundaries are set at 60° N and 60° S. The basic
focus of the paper is on the demonstration of the performance of the model and its assessment by employing appropriate forcing
from the outputs of an atmospheric general circulation model. Hence, the model was forced with the forcing (wind and thermodynamic)
derived from the ECMWF runs from the AMIP archives. The preliminary results show the realistic simulation of basic pattern
of different fields. The model simulations show that the model is able to reproduce some of the general features of the ocean,
such as surface currents, surface temperature and salinity, mass transport and meridional heat transport. It is also to be
noted that the model is capable to capture the El-Ni?o and La-Ni?a type events.
Received April 3, 2002; revised June 6, 2002; accepted July 24, 2002
Published online: February 20, 2003 相似文献
6.
The inter-basin teleconnection between the North Atlantic and the North Pacific ocean–atmosphere interaction is studied using
a coupled ocean–atmosphere general circulation model. In the model, an idealized oceanic temperature anomaly is initiated
over the Kuroshio and the Gulf Stream extension region to track the coupled evolution of ocean and atmosphere interaction,
respectively. The experiments explicitly demonstrate that both the North Pacific and the North Atlantic ocean–atmosphere interactions
are intimately coupled through an inter-basin atmospheric teleconnection. This fast inter-basin communication can transmit
oceanic variability between the North Atlantic and the North Pacific through local ocean-to-atmosphere feedbacks. The leading
mode of the extratropical atmospheric internal variability plays a dominant role in shaping the hemispheric-scale response
forced by oceanic variability over the North Atlantic and Pacific. Modeling results also suggest that a century (two centuries)
long observations are necessary for the detection of Pacific response to Atlantic forcings (Atlantic response to Pacific forcing). 相似文献
7.
A. Ganopolski V. Petoukhov S. Rahmstorf V. Brovkin M. Claussen A. Eliseev C. Kubatzki 《Climate Dynamics》2001,17(10):735-751
A set of sensitivity experiments with the climate system model of intermediate complexity CLIMBER-2 was performed to compare
its sensitivity to changes in different types of forcings and boundary conditions with the results of comprehensive models
(GCMs). We investigated the climate system response to changes in freshwater flux into the Northern Atlantic, CO2 concentration, solar insolation, and vegetation cover in the boreal zone and in the tropics. All these experiments were compared
with the results of corresponding experiments performed with different GCMs. Qualitative, and in many respects, quantitative
agreement between the results of CLIMBER-2 and GCMs demonstrate the ability of our climate system model of intermediate complexity
to address diverse aspects of the climate change problem. In addition, we used our model for a series of experiments to assess
the impact of some climate feedbacks and uncertainties in model parameters on the model sensitivity to different forcings.
We studied the role of freshwater feedback and vertical ocean diffusivity for the stability properties of the thermohaline
ocean circulation. We show that freshwater feedback plays a minor role, while changes of vertical diffusivity in the ocean
considerably affect the circulation stability. In global warming experiments we analysed the impact of hydrological sensitivity
and vertical diffusivity on the long-term evolution of the thermohaline circulation. In the boreal and tropical deforestation
experiments we assessed the role of an interactive ocean and showed that for both types of deforestation scenarios, an interactive
ocean leads to an additional cooling due to albedo and water vapour feedbacks.
Received: 28 May 2000 / Accepted: 9 November 2000 相似文献
8.
Ph. Drobinski S. Bastin J. Dusek G. Zängl P. H. Flamant 《Meteorology and Atmospheric Physics》2006,92(3-4):285-306
Summary This paper investigates the characteristics of channelled airflow in the vicinity of a junction of three idealized valleys
(one valley carrying the incoming flow and two tributaries carrying the outflow), using a two-dimensional single-layer shallow
water model. Particular attention is given to the flow splitting occurring at the junction. Nondimensionalized, the model
depends on the valley geometry, the Reynolds number, which is related to the eddy viscosity, and on the difference of the
hydrostatic pressure imposed at the exit of the tributaries. At the spatial scale considered in this study, the Rossby number
relating the inertial and Coriolis forces is always larger than 1, implying that the effect of earth rotation can be neglected
to a first approximation.
The analysis of the flow structure within the three valleys as well as the calculation of the split ratio (fraction of the
air flow diverted into one of the two downstream valleys with respect to the total mass flux in the upstream valley) show
that (i) the flow pattern depends strongly on the Reynolds number while the split ratio is comparatively insensitive; (ii)
the valley geometry and the difference between the upstream and downstream hydrostatic pressures affect the flow pattern,
the location of the split point and the split ratio; (iii) the relative contribution of flow deflection by the sidewalls and
the blocking/splitting mechanism differs between the settings of a “Y-shape” valley and a “T-shape” valley.
Quantitative comparison of the present results with numerical simulations of realistic cases and with observations collected
in the region of the Rhine and Seez valleys (Switzerland) (“Y-shape” valley) and in the region of the Inn and Wipp valleys
(Austria) (“T-shape” valley) during the Mesoscale Alpine Programme (MAP) field experiment shows good agreement provided that
the normalized valley depth NΔH/Uu significantly exceeds 1, i.e., when “flow around” is expected. A structural disagreement between the idealized simulations
and the observed wind field is found only when NΔH/Uu ≃ 1, that is, in the “flow over” regime. This shows that the dimensionless valley depth
is indeed a good indicator for flow splitting, implying that the stratification is a key player in reality. 相似文献
9.
The coupling of optimal economic growth and climate dynamics 总被引:1,自引:0,他引:1
Olivier Bahn Laurent Drouet Neil R. Edwards Alain Haurie Reto Knutti Socrates Kypreos Thomas F. Stocker Jean-Philippe Vial 《Climatic change》2006,79(1-2):103-119
In this paper, we study optimal economic growth programs coupled with climate change dynamics. The study is based on models derived from MERGE, a well established integrated assessment model (IAM). We discuss first the introduction in MERGE of a set of “tolerable window” constraints which limit both the temperature change and the rate of temperature change. These constraints, obtained from ensemble simulations performed with the Bern 2.5-D climate model, allow us to identity a domain intended to preserve the Atlantic thermohaline circulation. Next, we report on experiments where a two-way coupling is realized between the economic module of MERGE and an intermediate complexity “3-D-” climate model (C-GOLDSTEIN) which computes the changes in climate and mean temperature. The coupling is achieved through the implementation of an advanced “oracle based optimization technique” which permits the integration of information coming from the climate model during the search for the optimal economic growth path. Both cost-effectiveness and cost-benefit analysis modes are explored with this combined “meta-model” which we refer to as GOLDMERGE. Some perspectives on future implementations of these approaches in the context of “collaborative” or “community” integrated assessment modules are derived from the comparison of the different approaches. 相似文献
10.
Summary A simple 1.5 layer reduced gravity transport model is used to understand the influence of a moving tropical cyclone on the upper layer of the Bay of Bengal. The wind stress used to force the model is derived from an idealised cyclone. The model cyclone is considered to be a symmetric vortex with both tangential and radial winds. The cyclone center moves northwestwards between the points 97E, 8N and 82E, 23N. In the control experiment, the cyclone is allowed to move the total distance in 5 days. The oceanic response is asymmetric in contrast to the symmetric wind forcings. Right bias found in the maxima of model circulation and upper layer thickness deviations, is in agreement with other modelling studies.Fifteen sensitivity experiments are carried out by varying the intensity, size and speed of the cyclone, by changing the model parameters and with different initial conditions. Model fields show linear response to changes in the intensity and size of the cyclone. The changes in the maximum wind of the cyclone produces highest variability in the model fields. Increase in model resolution in association with the corresponding decrease in viscosity results in the enhancement of maxima of the flow magnitude and ULTD. Increasing the phase speed of the initial mode results in a wider spreading of energy and hence decrease in the flow intensity and the upper layer deviations. Model results do not show much variation by considering different initial conditions.With 9 Figures 相似文献
11.
Numerical convergence of the dynamics of a GCM 总被引:1,自引:0,他引:1
Atmospheric general circulation models (GCMs) are characterized by many features but especially by: (1) the manner of discretizing the governing equations and of representing the variables involved at a given resolution, and (2) the manner of parameterizing unresolved physical processes in terms of those resolved variables. These two aspects of model formulation are not independent
and it is difficult to untangle their intertwined effects when assessing model performance. The attempt here is to separate
these aspects of GCM behaviour and to ask, “Given a perfect parameterization of the physical processes in a model, what resolution is needed to capture the dominant dynamical aspects
of the atmospheric climate?” Alternatively, “At what resolution do the dynamics of a GCM converge”? The perfect parameterization
approach assumes that the calculation of the physical terms returns the “correct” result at all resolutions. In the idealized
case, a time-independent forcing is one of the simplest that satisfies this condition. However, experiments show that it is
difficult for the dynamics of a GCM to balance a time-independent forcing with atmosphere-like flows and structures. The model
requires, and the atmosphere presumably includes, physical feedback mechanisms which act so as to maintain the kinds of flows
and structures that are observed. Resolution experiments are performed with a simplified forcing function for the thermodynamic
equation which combines a dominant time-independent specified forcing with a weak linear relaxation feedback. These experiments
show that the dynamics of the GCM have essentially converged at T32 and certainly by T63 which is the next resolution considered.
This is shown by the constancy of structures, variances, covariances, transports and energy budgets with increasing resolution.
Experiments with an alternative forcing proposed by Held and Suarez, which has the form of a linear relaxation, show somewhat
less evidence of convergence at these resolutions. In both cases the “physics” are known by assumption. However, the form
and nature of the forcing is different, as is the behaviour with resolution. The implication for the real system is that the
resolution required for simulating the dynamical aspects of climate is rather modest. The simulated climate does, however, apparently depend on the ability to correctly and
consistently parameterize the physical processes in a GCM, involving both forcing and feedback mechanisms, as a function of
resolution.
Received 19 January 1996/Accepted 22 August 1996 相似文献
12.
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
13.
A statistical test has revealed that abrupt regional climate changes are produced in a coupled atmosphere-ocean general circulation
model. Abrupt changes are detected over much of the globe although the occurrence frequency is small over the continents.
Over the tropical Pacific Ocean and northern Pacific Ocean, surface air temperature (SAT) and sea level pressure (SLP) shift
rapidly on decadal time scales. The regional climate changes presented here have been classified into three types. The first
type consists of statistically significant shifts in SLP and statistically significant shifts in SAT which are of opposite
sign, and which are reinforced through a positive feedback between the atmosphere and the ocean. The second type is for those
occurrences where changes are of the same sign. The third type includes those with a significant shift in only one meteorological
element. The second and third types are generally generated by changes in air pressure and wind fields induced by changes
of the first type. For example, when SLP increases and sea surface temperature (SST) decreases abruptly in the tropical Pacific
Ocean, it triggers abrupt regional changes in middle and high latitudes. The abrupt changes in the model climate have characteristics
which are very similar to those of observed rapid shifts. Thus, it is concluded that abrupt changes are a predominant part
of regional climate change on decadal time scales.
Received: 11 February 1999 / Accepted: 18 May 2000 相似文献
14.
Summary The boundary-layer wind field during weak synoptic conditions is largely controlled by the nature of the landscape. Mesoscale
(sub-synoptic) circulations result from horizontal gradients of sensible heat flux due to variation in local topography, variation
in surface-cover, and discontinuities such as land-sea contrasts. Such flows are usually referred to as thermally-driven circulations,
and are diurnal in nature and often predictable. In this paper we use a state-of-the-art non-hydrostatic computer model to
shed light on the physical mechanisms that drive a persistent easterly wind that develops in the afternoon in the Mackenzie
Basin, New Zealand. The easterly – Canterbury Plains Breeze (CPB) – is observed early in the afternoon and is often intense,
with mean wind speeds reaching up to 12 m s−1. Although computer modelling in mountainous terrain is extremely challenging, the model is able to simulate this circulation
satisfactorily. To further investigate the mechanisms that generate the Canterbury Plains Breeze, two additional idealized
model experiments are performed. With each experiment, the effects of the synoptic scale wind and the ocean around the South
Island, New Zealand were successively removed. The results show that contrary to previous suggestions, the Canterbury Plains
Breeze is not an intrusion of the coastal sea breeze or the Canterbury north-easterly, but can be generated by heating of
the basin alone. This conclusion highlights the importance of mountain basins and saddles in controlling near-surface wind
regimes in complex terrain. 相似文献
15.
A time-slice experiment with the ECHAM4 AGCM at high resolution: the impact of horizontal resolution on annual mean climate change 总被引:2,自引:0,他引:2
The climate response to increasing levels of atmospheric greenhouse gases, prescribed according to the International Panel
of Climate Change (IPCC) scenario IS92a, is studied in two model simulations. The reference simulation is a transient response
experiment performed with a medium-resolution (T42) coupled general circulation model of the atmosphere and ocean (ECHAM4/OPYC)
developed at the Max-Planck-Institute for Meteorology. For two 30-year “time slices”, representing the present-day climate
and the future climate at the time of effective CO2 doubling, the annual mean climate states are compared with those obtained from the high-resolution (T106) ECHAM4 model forced
with monthly sea surface temperatures and sea-ice from the coupled model. The large-scale changes in temperature, zonal wind,
sea-level pressure and precipitation are broadly similar. This applies, in particular, to the respective zonal means. In general,
except for precipitation, the responses in the time-slice experiments are slightly weaker than those simulated in the coupled
model due to a smaller effect of the horizontal resolution on the simulations of the future (warmer) period than on the simulations
of the present period. On a regional scale, the impact of horizontal resolution is smaller in the Southern than in the Northern
Hemisphere, where the response differences are caused mainly by changes in the positions of the stationary waves. Although
the precipitation responses are broadly similar, there are few notable exceptions such as a more pronounced maximum over the
equatorial oceans in the T106 experiment but a weaker response over low-latitude land areas. Differences in precipitation
response are found especially in areas with strong topographical control such as South America, for example.
Received: 17 January 2000 / Accepted: 7 July 2000 相似文献
16.
Sensitivity of the thermohaline circulation and climate to ocean exchanges in a simple coupled model 总被引:2,自引:0,他引:2
A new simple, coupled climate model is presented and used to investigate the sensitivity of the thermohaline circulation
and climate to ocean vertical and horizontal exchange. As formulated, the model highlights the role of thin, ocean surface
layers in the communication between the atmosphere and the subsurface ocean. Model vertical exchange is considered to be an
analogue to small-scale, diapycnal mixing and convection (when present) in the ocean. Model horizontal exchange is considered
to be an analogue to the effects of the wind-driven circulation. For small vertical exchange in the ocean, the model exhibits
only one steady-state solution: a relatively cold, mid-high-latitude climate associated with a weak, salinity-driven circulation
(“off ” mode). For large vertical and horizontal exchange in the ocean, the model also exhibits only one steady-state solution:
a relatively warm, mid-high-latitude climate associated with a strong, thermally-driven circulation (“on” mode). For sufficiently
weak horizontal exchange but large enough vertical exchange, both modes are possible stable, steady-state solutions. When
model parameters are calibrated to fit tracer distributions of the modern ocean-atmosphere system, only the “on” mode is possible
in this standard case. This suggests that the wind-driven circulation in consort with diapycnal mixing suppresses the “off ”
mode in the modern ocean-atmosphere system. Since both diapycnal mixing and the wind-driven circulation would be expected
to increase in a cold climate with greater meridional temperature gradients and enhanced winds, vertical and horizontal exchange
in the ocean are probably associated with strong negative feedbacks which tend to stabilize climate. These results point to
the need to resolve ocean wind-driven circulation and to greatly improve the treatment of ocean diapycnal mixing in more complete
models of the climate system.
Received: 16 November 1999 / Accepted: 19 June 2000 相似文献
17.
Stabilization of thermohaline circulation by wind-driven and vertical diffusive salt transport 总被引:1,自引:0,他引:1
The stability of the thermohaline circulation is investigated using an ocean general circulation model coupled to a simple
atmospheric model. The atmospheric model is so developed that it represents the wind stress and the freshwater flux more realistically
than existing energy balance models. The coupled model can reproduce the realistic deep ocean circulation without any flux
adjustment. Effects of the wind stress and the vertical diffusion on the thermohaline circulation are studied by conducting
various experiments with the coupled model. The Ekman upwelling between 60∘N and 90∘N brings up salt to the sea surface, while the compensation flow of the Ekman transport and the wind-driven gyre circulation
between 30∘N and 60∘N carry salt horizontally to the high latitudes. By carrying out experiments where the wind stress is completely or partly
removed, it is demonstrated that either of the vertical or the horizontal salt transport prevents the halocline formation
at high latitudes and maintains the thermohaline circulation. For an experiment in which the vertical diffusivity is enhanced
at high latitudes, it is shown that the vertical diffusion at high latitudes also prevents the halocline formation and stabilizes
the thermohaline circulation. It is also shown that the value of the vertical diffusivity at high latitude affects the existence
of the multiple equilibria of the thermohaline circulation.
Received: 26 April 2000 / Accepted: 10 January 2001 相似文献
18.
Closure of the Panama Seaway during the Pliocene: implications for climate and Northern Hemisphere glaciation 总被引:1,自引:1,他引:0
The “Panama Hypothesis” states that the gradual closure of the Panama Seaway, between 13 million years ago (13 Ma) and 2.6 Ma,
led to decreased mixing of Atlantic and Pacific water Masses, the formation of North Atlantic Deep water and strengthening
of the Atlantic thermohaline circulation, increased temperatures and evaporation in the North Atlantic, increased precipitation
in Northern Hemisphere (NH) high latitudes, culminating in the intensification of Northern Hemisphere Glaciation (NHG) during
the Pliocene, 3.2–2.7 Ma. Here we test this hypothesis using a fully coupled, fully dynamic ocean-atmosphere general circulation
model (GCM) with boundary conditions specific to the Pliocene, and a high resolution dynamic ice sheet model. We carry out
two GCM simulations with “closed” and “open” Panama Seaways, and use the simulated climatologies to force the ice sheet model.
We find that the models support the “Panama Hypothesis” in as much as the closure of the seaway results in a more intense
Atlantic thermohaline circulation, enhanced precipitation over Greenland and North America, and ultimately larger ice sheets.
However, the volume difference between the ice sheets in the “closed” and “open” configurations is small, equivalent to about
5 cm of sea level. We conclude that although the closure of the Panama Seaway may have slightly enhanced or advanced the onset
of NHG, it was not a major forcing mechanism. Future work must fully couple the ice sheet model and GCM, and investigate the
role of orbital and CO2 effects in controlling NHG. 相似文献
19.
A hybrid coupled model (HCM) for the tropical Pacific ocean-atmosphere system is employed for ENSO prediction. The HCM consists
of the Geophysical Fluid Dynamics Laboratory ocean general circulation model and an empirical atmospheric model. In hindcast
experiments, a correlation skill competitive to other prediction models is obtained, so we use this system to examine the
effects of several initialization schemes on ENSO prediction. Initialization with wind stress data and initialization with
wind stress reconstructed from SST using the atmospheric model give comparable skill levels. In re-estimating the atmospheric
model in order to prevent hindcast-period wind information from entering through empirical atmospheric model, we note some
sensitivity to the estimation data set, but this is considered to have limited impact for ENSO prediction purposes. Examination
of subsurface heat content anomalies in these cases and a case forced only by the difference between observed and reconstructed
winds suggests that at the current level of prediction skill, the crucial wind components for initialization are those associated
with the slow ENSO mode, rather than with atmospheric internal variability. A “piggyback” suboptimal data assimilation is
tested in which the Climate Prediction Center data assimilation product from a related ocean model is used to correct the
ocean initial thermal field. This yields improved skill, suggesting that not all ENSO prediction systems need to invest in
costly data assimilation efforts, provided the prediction and assimilation models are sufficiently close.
Received: 17 April 1998 / Accepted: 22 July 1999 相似文献
20.
K. P. Sooraj Daehyun Kim Jong-Seong Kug Sang-Wook Yeh Fei-Fei Jin In-Sik Kang 《Climate Dynamics》2009,33(4):495-507
Recently, there is increasing evidence on the interaction of atmospheric high-frequency (HF) variability with climatic low-frequency
(LF) variability. In this study, we examine this relationship of HF variability with large scale circulation using idealized
experiments with an aqua-planet Atmospheric GCM (with zonally uniform SST), run in different zonal momentum forcing scenarios.
The effect of large scale circulation changes to the HF variability is demonstrated here. The HF atmospheric variability is
enhanced over the westerly forced region, through easterly vertical shear. Our study also manifests that apart from the vertical
wind shear, strong low-level convergence and horizontal zonal wind shear are also important for enhancing the HF variance.
This is clearly seen in the eastern part of the forcing, where the HF activity shows relatively maximum increase, in spite
of similar vertical shear over the forced regions. The possible implications for multi-scale interaction (e.g. MJO–ENSO interaction)
are also discussed. 相似文献