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1.
The predictability of atmospheric responses to global sea surface temperature (SST) anomalies is evaluated using ensemble
simulations of two general circulation models (GCMs): the GENESIS version 1.5 (GEN) and the ECMWF cycle 36 (ECM). The integrations
incorporate observed SST variations but start from different initial land and atmospheric states. Five GEN 1980–1992 and six
ECM 1980–1988 realizations are compared with observations to distinguish predictable SST forced climate signals from internal
variability. To facilitate the study, correlation analysis and significance evaluation techniques are developed on the basis
of time series permutations. It is found that the annual mean global area with realistic signals is variable dependent and
ranges from 3 to 20% in GEN and 6 to 28% in ECM. More than 95% of these signal areas occur between 35 °S–35 °N. Due to the
existence of model biases, robust responses, which are independent of initial condition, are identified over broader areas.
Both GCMs demonstrate that the sensitivity to initial conditions decreases and the predictability of SST forced responses
increases, in order, from 850 hPa zonal wind, outgoing longwave radiation, 200 hPa zonal wind, sea-level pressure to 500 hPa
height. The predictable signals are concentrated in the tropical and subtropical Pacific Ocean and are identified with typical
El Ni?o/ Southern Oscillation phenomena that occur in response to SST and diabatic heating anomalies over the equatorial central
Pacific. ECM is less sensitive to initial conditions and better predicts SST forced climate changes. This results from (1)
a more realistic basic climatology, especially of the upper-level wind circulation, that produces more realistic interactions
between the mean flow, stationary waves and tropical forcing; (2) a more vigorous hydrologic cycle that amplifies the tropical
forcing signals, which can exceed internal variability and be more efficiently transported from the forcing region. Differences
between the models and observations are identified. For GEN during El Ni?o, the convection does not carry energy to a sufficiently
high altitude, while the spread of the tropospheric warming along the equator is slower and the anomaly magnitude smaller
than observed. This impacts model ability to simulate realistic responses over Eurasia and the Indian Ocean. Similar biases
exist in the ECM responses. In addition, the relationships between upper and lower tropospheric wind responses to SST forcing
are not well reproduced by either model. The identification of these model biases leads to the conclusion that improvements
in convective heat and momentum transport parametrizations and basic climate simulations could substantially increase predictive
skill.
Received: 25 April 1996 / Accepted: 9 December 1996 相似文献
2.
Uncertainties in regional climate change prediction: a regional analysis of ensemble simulations with the HADCM2 coupled AOGCM 总被引:2,自引:2,他引:0
We analyze ensembles (four realizations) of historical and future climate transient experiments carried out with the coupled
atmosphere-ocean general circulation model (AOGCM) of the Hadley Centre for Climate Prediction and Research, version HADCM2,
with four scenarios of greenhouse gas (GHG) and sulfate forcing. The analysis focuses on the regional scale, and in particular
on 21 regions covering all land areas in the World (except Antarctica). We examine seasonally averaged surface air temperature
and precipitation for the historical period of 1961–1990 and the future climate period of 2046–2075. Compared to previous
AOGCM simulations, the HADCM2 model shows a good performance in reproducing observed regional averages of summer and winter
temperature and precipitation. The model, however, does not reproduce well observed interannual variability. We find that
the uncertainty in regional climate change predictions associated with the spread of different realizations in an ensemble
(i.e. the uncertainty related to the internal model variability) is relatively low for all scenarios and regions. In particular,
this uncertainty is lower than the uncertainty due to inter-scenario variability and (by comparison with previous regional
analyses of AOGCMs) with inter-model variability. The climate biases and sensitivities found for different realizations of
the same ensemble were similar to the corresponding ensemble averages and the averages associated with individual realizations
of the same ensemble did not differ from each other at the 5% confidence level in the vast majority of cases. These results
indicate that a relatively small number of realizations (3 or 4) is sufficient to characterize an AOGCM transient climate
change prediction at the regional scale.
Received: 12 January 1998 / Accepted: 7 July 1999 相似文献
3.
Coupled ocean-atmosphere models with flux correction 总被引:11,自引:3,他引:11
A method is proposed for removing the drift of coupled atmosphere-ocean models, which in the past has often hindered the application of coupled models in climate response and sensitivity experiments. The ocean-atmosphere flux fields exhibit inconsistencies when evaluated separately for the individual sub-systems in independent, uncoupled mode equilibrium climate computations. In order to balance these inconsistencies a constant ocean-atmosphere flux correction field is introduced in the boundary conditions coupling the two sub-systems together. The method ensures that the coupled model operates at the reference climate state for which the individual model subsystems were designed without affecting the dynamical response of the coupled system in climate variability experiments. The method is illustrated for a simple two component box model and an ocean general circulation model coupled to a two layer diagnostic atmospheric model. 相似文献
4.
By using IAP 9L AGCM, two sets of long-term climatological integration have been per-formed with the two different interpolation procedures for generating the daily surface boundary conditions. One interpolation procedure is the so-called “traditional” scheme, for which the daily surface boundary conditions are obtained by linearly interpolating between the observed monthly mean values, however the observed monthly means cannot be preserved after interpolation. The other one is the “new” scheme, for which the daily surface boundary conditions are obtained by linearly interpolating between the "artificial" monthly mean values which are based on, but are dif-ferent from the observed ones, after interpolating with this new scheme, not only the observed monthly mean values are preserved, the time series of the new generated daily values is also more consistent with the observation. Comparison of the model results shows that the differences of the globally or zonally averaged fields between these two integrations are quite small, and this is due to the compensating effect between the different regions. However, the differences of the two patterns (the global or regional geographical distributions), are quite significant, for example, the magni-tude of the difference in the JJA mean rainfall between these two integrations can exceed 2 mm/day over Asian monsoon regions, and the difference in DJF mean surface air temperature can also exceed 2oC over this region. The fact that the model climatology depends quite strongly on the method of prescribing the daily surface boundary conditions suggests that in order to validate the climate model or to predict the short-term climate anomalies, either the " new* interpolation scheme or the high frequency surface boundary conditions (e.g., daily or weekly data instead of the monthly data) should be introduced. Meanwhile, as for the coupled model, the daily coupling scheme between the different component cli?mate models (e.g., atmospheric and oceanic general circulation models) is preferred in order to partly eliminate the “climate drift” problem which may appear during the course of direct coupling. 相似文献
5.
A statistical model to downscale local daily temperature extremes from synoptic-scale atmospheric circulation patterns in the Australian region 总被引:3,自引:0,他引:3
The study seeks to describe one method of deriving information about local daily temperature extremes from larger scale atmospheric
flow patterns using statistical tools. This is considered to be one step towards downscaling coarsely gridded climate data
from global climate models (GCMs) to finer spatial scales. Downscaling is necessary in order to bridge the spatial mismatch
between GCMs and climate impact models which need information on spatial scales that the GCMs cannot provide. The method of
statistical downscaling is based on physical interaction between atmospheric processes with different spatial scales, in this
case between synoptic scale mean sea level pressure (MSLP) fields and local temperature extremes at several stations in southeast
Australia. In this study it was found that most of the day-to-day spatial variability of the synoptic circulation over the
Australian region can be captured by six principal components. Using the scores of these PCs as multivariate indicators of
the circulation a substantial part of the local daily temperature variability could be explained. The inclusion of temperature
persistence noticeably improved the performance of the statistical model. The model established and tested with observations
is thought to be finally applied to GCM-simulated pressure fields in order to estimate pressure-related changes in local temperature
extremes under altered CO2 conditions.
Received: 26 March 1996 / Accepted: 20 September 1996 相似文献
6.
Internal variability of RCM simulations over an annual cycle 总被引:1,自引:0,他引:1
Three one-year simulations generated with the Canadian RCM (CRCM) are compared to each other in order to study internal variability in nested regional climate models and to evaluate the influence exerted by the lateral boundaries information supplied by the nesting procedure. All simulations are generated over a large domain and cover an annual cycle. The simulations use different combinations of surface and atmospheric initial conditions but all of them share the same set of time-dependent lateral boundary conditions taken from a simulation by the Canadian GCM. A first simulation is used as control, the second simulation is launched with different atmospheric and surface initial conditions (IC) and the third simulation is launched taking its surface IC from the control simulation. Comparison of the root-mean-square differences (RMSD) between each pair of simulations shows two distinct seasonal behaviours in the time series of the RMSD. In winter all simulations are almost identical to each other resulting in very low RMSD values while in summer large discrepancies develop between pairs of simulations. For water vapour related fields such as precipitation or specific humidity, these discrepancies are sometimes as large as the monthly averaged variability. However, analysis of the climate statistics shows that, although the evolution of the various summer weather systems is different, the climates of each simulation are similar. 相似文献
7.
The CNRM atmospheric general circulation model Arpege-Climat is relaxed towards atmospheric reanalyses outside the 10°S?C32°N 30°W?C50°E domain in order to disentangle the regional versus large-scale sources of climatological biases and interannual variability of the West African monsoon (WAM). On the one hand, the main climatological features of the monsoon, including the spatial distribution of summer precipitation, are only weakly improved by the nudging, thereby suggesting the regional origin of the Arpege-Climat biases. On the other hand, the nudging technique is relatively efficient to control the interannual variability of the WAM dynamics, though the impact on rainfall variability is less clear. Additional sensitivity experiments focusing on the strong 1994 summer monsoon suggest that the weak sensitivity of the model biases is not an artifact of the nudging design, but the evidence that regional physical processes are the main limiting factors for a realistic simulation of monsoon circulation and precipitation in the Arpege-Climat model. Sensitivity experiments to soil moisture boundary conditions are also conducted and highlight the relevance of land?Catmosphere coupling for the amplification of precipitation biases. Nevertheless, the land surface hydrology is not the main explanation for the model errors that are rather due to deficiencies in the atmospheric physics. The intraseasonal timescale and the model internal variability are discussed in a companion paper. 相似文献
8.
Christoph C. Raible Carlo Casty Jürg Luterbacher Andreas Pauling Jan Esper David C. Frank Ulf Büntgen Andreas C. Roesch Peter Tschuck Martin Wild Pier-Luigi Vidale Christoph Schär Heinz Wanner 《Climatic change》2006,79(1-2):9-29
A detailed analysis is undertaken of the Atlantic-European climate using data from 500-year-long proxy-based climate reconstructions, a long climate simulation with perpetual 1990 forcing, as well as two global and one regional climate change scenarios. The observed and simulated interannual variability and teleconnectivity are compared and interpreted in order to improve the understanding of natural climate variability on interannual to decadal time scales for the late Holocene. The focus is set on the Atlantic-European and Alpine regions during the winter and summer seasons, using temperature, precipitation, and 500 hPa geopotential height fields. The climate reconstruction shows pronounced interdecadal variations that appear to “lock” the atmospheric circulation in quasi-steady long-term patterns over multi-decadal periods controlling at least part of the temperature and precipitation variability. Different circulation patterns are persistent over several decades for the period 1500 to 1900. The 500-year-long simulation with perpetual 1990 forcing shows some substantial differences, with a more unsteady teleconnectivity behaviour. Two global scenario simulations indicate a transition towards more stable teleconnectivity for the next 100 years. Time series of reconstructed and simulated temperature and precipitation over the Alpine region show comparatively small changes in interannual variability within the time frame considered, with the exception of the summer season, where a substantial increase in interannual variability is simulated by regional climate models. 相似文献
9.
10.
Summary Regional climate model and statistical downscaling procedures are used to generate winter precipitation changes over Romania
for the period 2071–2100 (compared to 1961–1990), under the IPCC A2 and B2 emission scenarios. For this purpose, the ICTP
regional climate model RegCM is nested within the Hadley Centre global atmospheric model HadAM3H. The statistical downscaling
method is based on the use of canonical correlation analysis (CCA) to construct climate change scenarios for winter precipitation
over Romania from two predictors, sea level pressure and specific humidity (either used individually or together). A technique
to select the most skillful model separately for each station is proposed to optimise the statistical downscaling signal.
Climate fields from the A2 and B2 scenario simulations with the HadAM3H and RegCM models are used as input to the statistical
downscaling model. First, the capability of the climate models to reproduce the observed link between winter precipitation
over Romania and atmospheric circulation at the European scale is analysed, showing that the RegCM is more accurate than HadAM3H
in the simulation of Romanian precipitation variability and its connection with large-scale circulations. Both models overestimate
winter precipitation in the eastern regions of Romania due to an overestimation of the intensity and frequency of cyclonic
systems over Europe. Climate changes derived directly from the RegCM and HadAM3H show an increase of precipitation during
the 2071–2100 period compared to 1961–1990, especially over northwest and northeast Romania. Similar climate change patterns
are obtained through the statistical downscaling method when the technique of optimum model selected separately for each station
is used. This adds confidence to the simulated climate change signal over this region. The uncertainty of results is higher
for the eastern and southeastern regions of Romania due to the lower HadAM3H and RegCM performance in simulating winter precipitation
variability there as well as the reduced skill of the statistical downscaling model. 相似文献
11.
L. C. Sloan 《Theoretical and Applied Climatology》2006,86(1-4):271-279
Summary The methods of reconstructing ancient climate information from the rock record are summarized, and the climate forcing factors
that have been active at global and regional scales through Earth history are reviewed. In this context, the challenges and
approaches to modeling past climates by using a regional climate model are discussed. A significant challenge to such modeling
efforts arises if the time period of interest occurred prior to the past ∼3–5 million years, at which point land–sea distributions
and topography markedly different from present must be specified at the spatial resolution required by regional climate models.
Creating these boundary conditions requires a high degree of geologic knowledge, and also depends greatly upon the global
climate model driving conditions. Despite this and other challenges, regional climate models represent an important and unique
tool for paleoclimate investigations. Application of regional climate models to paleoclimate studies may provide another way
to assess the overall performance of regional climate models. 相似文献
12.
One of the main concerns in regional climate modeling is to which extent limited-area regional climate models (RCM) reproduce
the large-scale atmospheric conditions of their driving general circulation model (GCM). In this work we investigate the ability
of a multi-model ensemble of regional climate simulations to reproduce the large-scale weather regimes of the driving conditions.
The ensemble consists of a set of 13 RCMs on a European domain, driven at their lateral boundaries by the ERA40 reanalysis
for the time period 1961–2000. Two sets of experiments have been completed with horizontal resolutions of 50 and 25 km, respectively.
The spectral nudging technique has been applied to one of the models within the ensemble. The RCMs reproduce the weather regimes
behavior in terms of composite pattern, mean frequency of occurrence and persistence reasonably well. The models also simulate
well the long-term trends and the inter-annual variability of the frequency of occurrence. However, there is a non-negligible
spread among the models which is stronger in summer than in winter. This spread is due to two reasons: (1) we are dealing
with different models and (2) each RCM produces an internal variability. As far as the day-to-day weather regime history is
concerned, the ensemble shows large discrepancies. At daily time scale, the model spread has also a seasonal dependence, being
stronger in summer than in winter. Results also show that the spectral nudging technique improves the model performance in
reproducing the large-scale of the driving field. In addition, the impact of increasing the number of grid points has been
addressed by comparing the 25 and 50 km experiments. We show that the horizontal resolution does not affect significantly
the model performance for large-scale circulation. 相似文献
13.
Relative contribution of soil moisture and snow mass to seasonal climate predictability: a pilot study 总被引:1,自引:1,他引:0
Hervé Douville 《Climate Dynamics》2010,34(6):797-818
Land surface hydrology (LSH) is a potential source of long-range atmospheric predictability that has received less attention
than sea surface temperature (SST). In this study, we carry out ensemble atmospheric simulations driven by observed or climatological
SST in which the LSH is either interactive or nudged towards a global monthly re-analysis. The main objective is to evaluate
the impact of soil moisture or snow mass anomalies on seasonal climate variability and predictability over the 1986–1995 period.
We first analyse the annual cycle of zonal mean potential (perfect model approach) and effective (simulated vs. observed climate)
predictability in order to identify the seasons and latitudes where land surface initialization is potentially relevant. Results
highlight the influence of soil moisture boundary conditions in the summer mid-latitudes and the role of snow boundary conditions
in the northern high latitudes. Then, we focus on the Eurasian continent and we contrast seasons with opposite land surface
anomalies. In addition to the nudged experiments, we conduct ensembles of seasonal hindcasts in which the relaxation is switched
off at the end of spring or winter in order to evaluate the impact of soil moisture or snow mass initialization. LSH appears
as an effective source of surface air temperature and precipitation predictability over Eurasia (as well as North America),
at least as important as SST in spring and summer. Cloud feedbacks and large-scale dynamics contribute to amplify the regional
temperature response, which is however, mainly found at the lowest model levels and only represents a small fraction of the
observed variability in the upper troposphere. 相似文献
14.
We present an analysis of a multidecadal simulation of present-day climate (1961–1990) over Europe with the regional climate model RegCM nested within the global atmospheric model HadAMH. Climatic means, interannual variability and trends are examined, with focus on surface air temperature and precipitation. The RegCM driven by HadAMH fields is able to reproduce the basic features of the observed mean surface climate over Europe, its seasonal evolution and the regional detail due to topographic forcing. Surface air temperature biases are mostly less than 1–2 °C and precipitation biases mostly within 10–20%. The RegCM has more intense vertical transport of temperature and water vapor than HadAMH, which results in lower surface air temperatures and greater precipitation than found in the HadAMH simulation. In some cases this is in the direction of greater agreement with observations, while in others it is in the opposite direction. The simulation shows a tendency to overestimate interannual variability of temperature and precipitation compared to observations, particularly during summer and over the Mediterranean regions. It is shown that in DJF, MAM and SON the RegCM interannual variability is primarily determined by the boundary forcing from HadAMH, while in JJA the internal model physics and resolution effects dominate over many subregions of the domain, and the RegCM has higher interannual variability than HadAMH. The precipitation trends simulated by the nested modeling system for the period 1961–1990 capture some features of the observed trends, in particular the cold season drying over the Mediterranean regions. Ensembles of simulations are, however, needed for a more robust assessment of the models capability to simulate climatic trends. Overall, this simulation is of good quality compared with previous nested RegCM experiments and will constitute the basis for the generation of climate change scenarios over the European region to be reported in future work. 相似文献
15.
A general circulation model is used to examine the effects of reduced atmospheric CO2, insolation changes and an updated reconstruction of the continental ice sheets at the Last Glacial Maximum (LGM). A set
of experiments is performed to estimate the radiative forcing from each of the boundary conditions. These calculations are
used to estimate a total radiative forcing for the climate of the LGM. The response of the general circulation model to the
forcing from each of the changed boundary conditions is then investigated. About two-thirds of the simulated glacial cooling
is due to the presence of the continental ice sheets. The effect of the cloud feedback is substantially modified where there
are large changes to surface albedo. Finally, the climate sensitivity is estimated based on the global mean LGM radiative
forcing and temperature response, and is compared to the climate sensitivity calculated from equilibrium experiments with
atmospheric CO2 doubled from present day concentration. The calculations here using the model and palaeodata support a climate sensitivity
of about 1 Wm-2 K-1 which is within the conventional range.
Received: 8 February 1997 / Accepted: 4 June 1997 相似文献
16.
Anji Seth Sara A. Rauscher Suzana J. Camargo Jian-Hua Qian J. S. Pal 《Climate Dynamics》2007,28(5):461-480
To enable downscaling of seasonal prediction and climate change scenarios, long-term baseline regional climatologies which
employ global model forcing are needed for South America. As a first step in this process, this work examines climatological
integrations with a regional climate model using a continental scale domain nested in both reanalysis data and multiple realizations
of an atmospheric general circulation model (GCM). The analysis presents an evaluation of the nested model simulated large
scale circulation, mean annual cycle and interannual variability which is compared against observational estimates and also
with the driving GCM for the Northeast, Amazon, Monsoon and Southeast regions of South America. Results indicate that the
regional climate model simulates the annual cycle of precipitation well in the Northeast region and Monsoon regions; it exhibits
a dry bias during winter (July–September) in the Southeast, and simulates a semi-annual cycle with a dry bias in summer (December–February)
in the Amazon region. There is little difference in the annual cycle between the GCM and renalyses driven simulations, however,
substantial differences are seen in the interannual variability. Despite the biases in the annual cycle, the regional model
captures much of the interannual variability observed in the Northeast, Southeast and Amazon regions. In the Monsoon region,
where remote influences are weak, the regional model improves upon the GCM, though neither show substantial predictability.
We conclude that in regions where remote influences are strong and the global model performs well it is difficult for the
regional model to improve the large scale climatological features, indeed the regional model may degrade the simulation. Where
remote forcing is weak and local processes dominate, there is some potential for the regional model to add value. This, however,
will require improvments in physical parameterizations for high resolution tropical simulations. 相似文献
17.
The inter-annual variability in monthly mean summer temperatures derived from nine different regional climate model (RCM) integrations is investigated for both the control climate (1961–1990) and a future climate (2071–2100) based on A2 emissions. All regional model integrations, carried out in the PRUDENCE project, use the same boundaries of the HadAM3H global atmospheric model. Compared to the CRU TS 2.0 observational data set most RCMs (but not all) overpredict the temperature variability significantly in their control simulation. The behaviour of the different regional climate models is analysed in terms of the surface energy budget, and the contributions of the different terms in the surface energy budget to the temperature variability are estimated. This analysis shows a clear relation in the model ensemble between temperature variability and the combined effects of downward long wave, net short wave radiation and evaporation (defined as F). However, it appears that the overestimation of the temperature variability has no unique cause. The effect of short-wave radiation dominates in some RCMs, whereas in others the effect of evaporation dominates. In all models the temperature variability and F increase when imposing future climate boundary conditions, with particularly high values in central Europe. 相似文献
18.
GCM simulations of the Last Glacial Maximum surface climate of Greenland and Antarctica 总被引:3,自引:1,他引:2
The LMDz variable grid GCM was used to simulate the Last Glacial Maximum (LGM, 21 ky Bp.) climate of Greenland and Antarctica
at a spatial resolution of about 100 km.The high spatial resolution allows to investigate the spatial variability of surface
climate change signals, and thus to address the question whether the sparse ice core data can be viewed as representative
for the regional scale climate change. This study addresses primarily surface climate parameters because these can be checked
against the, limited, ice core record. The changes are generally stronger for Greenland than for Antarctica, as the imposed
changes of the forcing boundary conditions (e.g., sea surface temperatures) are more important in the vicinity of Greenland.
Over Greenland, and to a limited extent also in Antarctica, the climate shows stronger changes in winter than in summer. The
model suggests that the linear relationship between the surface temperature and inversion strength is modified during the
LGM. The temperature dependency of the moisture holding capacity of the atmosphere alone cannot explain the strong reduction
in snowfall over central Greenland; atmospheric circulation changes also play a crucial role. Changes in the high frequency
variability of snowfall, atmospheric pressure and temperature are investigated and possible consequences for the interpretation
of ice core records are discussed. Using an objective cyclone tracking scheme, the importance of changes of the atmospheric
dynamics off the coasts of the ice sheets, especially for the high frequency variability of surface climate parameters, is
illustrated. The importance of the choice of the LGM ice sheet topography is illustrated for Greenland, where two different
topographies have been used, yielding results that differ quite strongly in certain nontrivial respects. This means that the
paleo-topography is a significant source of uncertainty for the modelled paleoclimate. The sensitivity of the Greenland LGM
climate to the prescribed sea surface conditions is examined by using two different LGM North Atlantic data sets.
Received: 23 October 1997 / Accepted: 17 March 1998 相似文献
19.
Rapid transitions and ultra-low frequency behaviour in a 40 kyr integration with a coupled climate model of intermediate complexity 总被引:1,自引:0,他引:1
A 40 kyr integration with the coupled atmosphere/ocean/sea-ice model of intermediate complexity ECBilt for present boundary
conditions has been performed. The climate of ECBilt displays quasi-periodical behaviour with a period of approximately 13 kyr.
The quasi-periodical behaviour is characterized by large changes in the overturning cell in the Southern Ocean. The southern
cell fluctuates between two quasi-stationary states, with accompaning changes in the atmospheric circulation in the Southern
Hemisphere. The transition between these states is rapid and resembles the polar halocline catastrophes and flushes as observed
in ocean general circulation models under mixed boundary conditions. The sea-ice influence on both the surface heat and fresh
water flux appears to be crucial for the existence and the prolongation of the quasi-stationary states. The atmospheric circulation
of those two quasi-stationary states displays large regional differences over Antarctica, resulting in even opposite surface
air temperature trends for certain locations during the transition from one state to another.
Received: 7 October 1999 / Accepted: 28 August 2000 相似文献
20.
Atmosphere-only general circulation models are shown to be a useful tool for detecting an anthropogenic effect on climate
and understanding recent climate change. Ensembles of atmospheric runs are all forced with the same observed changes in sea
surface temperatures and sea-ice extents but differ in terms of the combinations of anthropogenic effects included. Therefore,
our approach aims to detect the `immediate' anthropogenic impact on the atmosphere as opposed to that which has arisen via
oceanic feedbacks. We have adapted two well-used detection techniques, pattern correlations and fingerprints, and both show
that near-decadal changes in the patterns of zonal mean upper air temperature are well simulated, and that it is highly unlikely
that the observed changes could be accounted for by sea surface temperature variations and internal variability alone. Furthermore,
we show that for zonally averaged upper air temperature, internal `noise' in the atmospheric model is small enough that a
signal emerges from the data even on interannual time scales; this would not be possible in a coupled ocean-atmosphere general
circulation model. Finally, although anthropogenic forcings have had a significant impact on global mean land surface temperature,
we find that their influence on the pattern of local deviations about this mean is so far undetectable. In order to achieve
this in the future, as the signal grows, it will also be important that the response of the Northern Hemisphere mid-latitude
westerly flow to changing sea surface temperatures is well simulated in climate model detection studies.
Received: 3 December 1999 / Accepted: 30 October 2000 相似文献