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1.
Dana Micu 《Meteorology and Atmospheric Physics》2009,105(1-2):1-16
Snow pack characteristics and duration are considered to be key indicators of climate change in mountain regions, especially during the winter season (herein considered to last from the 1st of November to the 30th of April). Deviations recorded in the regime of the main explanatory variables of snow pack changes (i.e. temperature and precipitation) offer useful information on winter climate variability, in the conditions of the winter warming trend already seen in some areas of the Romanian Carpathians. The present work focuses on changes and trends in snow pack characteristics and its related parameters, registered at the 15 weather stations located in the alpine, sub-alpine and forest belts in all the three Romanian Carpathian branches (>1,000 m) over the 1961–2003 period. Changes in the snow pack regime were investigated in relation with the modifications of winter temperature and precipitation having been detected mostly at the end of the twentieth century. A winter standardized index was calculated to group winters over the 43-year period into severity classes and detect the respective changes. Links between the number of snow cover days and seasonal NAO index were also statistically analysed in this study. The general results show large regional and altitudinal variations and the complex character of the climate in the Romanian Carpathians, leading to the idea of an ongoing warming process associated with a lower incidence of snow cover, affecting to a large extent the forested mountain areas located below 1,600–1,700 m altitude. Also negative and weak correlations were found, particularly over the December–March interval, between the number of snow cover days and seasonal NAO index values. 相似文献
2.
An analysis of climate change for global domain and for the European/Mediterranean region between the two periods, 1961–1990 (representing the twentieth century or “present” climate) and 2041–2070 (representing future climate), from the three-member ensemble of the EH5OM climate model under the IPCC A2 scenario was performed. Ensemble averages for winter and summer seasons were considered, but also intra-ensemble variations and the change of interannual variability between the two periods. First, model systematic errors are assessed because they could be closely related to uncertainties in climate change. A strengthening of westerlies (zonalization) over the northern Europe is associated with an erroneous increase in MSLP over the southern Europe. This increase in MSLP is related to a (partial) suppression of summer convective precipitation. Global warming in future climate is relatively uniform in the upper troposphere and it is associated with a 10% wind increase in the subtropical jet cores. However, spatial irregularities in the low-level temperature signal single out some regions as particularly sensitive to climate change. For Europe, the largest near-surface temperature increase in winter is found over its north-eastern part (more than 3°C), and the largest summer warming (over 3.5°C) is over south Europe. For south Europe, the increase in temperature averages is almost an order of magnitude larger than the increase in interannual variability. The magnitude of the warming is larger than the model systematic error, and the spread among the three model realisations is much smaller than the magnitude of climate change. This further supports the significance of estimated future temperature change. However, this is not the case for precipitation, implying therefore larger uncertainties for precipitation than for temperature in future climate projections. 相似文献
3.
European climate in the late twenty-first century: regional simulations with two driving global models and two forcing scenarios 总被引:15,自引:2,他引:13
A basic analysis is presented for a series of regional climate change simulations that were conducted by the Swedish Rossby Centre and contribute to the PRUDENCE (Prediction of Regional scenarios and Uncertainties for Defining EuropeaN Climate change risks and Effects) project. For each of the two driving global models HadAM3H and ECHAM4/OPYC3, a 30-year control run and two 30-year scenario runs (based on the SRES A2 and B2 emission scenarios) were made with the regional model. In this way, four realizations of climate change from 1961–1990 to 2071–2100 were obtained. The simulated changes are larger for the A2 than the B2 scenario (although with few qualitative differences) and in most cases in the ECHAM4/OPYC3-driven (RE) than in the HadAM3H-driven (RH) regional simulations. In all the scenario runs, the warming in northern Europe is largest in winter or late autumn. In central and southern Europe, the warming peaks in summer when it locally reaches 10 °C in the RE-A2 simulation and 6–7 °C in the RH-A2 and RE-B2 simulations. The four simulations agree on a general increase in precipitation in northern Europe especially in winter and on a general decrease in precipitation in southern and central Europe in summer, but the magnitude and the geographical patterns of the change differ markedly between RH and RE. This reflects very different changes in the atmospheric circulation during the winter half-year, which also lead to quite different simulated changes in windiness. All four simulations show a large increase in the lowest minimum temperatures in northern, central and eastern Europe, most likely due to reduced snow cover. Extreme daily precipitation increases even in most of those areas where the mean annual precipitation decreases. 相似文献
4.
Brian Huntley 《Climate Dynamics》1992,6(3-4):185-191
Rates of change of pollen spectra throughout Europe during the last 13 000 years have been calculated. The overall mean rate of change curve shows peaks corresponding to known times of rapid palaeoenvironmental change between 13 000 and 12000y BP, and between 10 000 and 9000 y BP. These peaks are strongest in the north and west of Europe. As in eastern North America (Jacobson et al. 1987), highest rates of change are recorded during the last millennium. At this time the changes of greatest magnitude are in areas of Europe with winter climate conditions strongly influenced by the North Atlantic. It is hypothesized that the overall pattern of Holocene climate change in Europe, and especially the changes of the last millennium, result from changes in the North Atlantic that have most strongly influenced winter conditions in western Europe.Contribution to Clima Locarno — Past and Present Climate Dynamics; Conference September 1990, Swiss Academy of Sciences — National Climate Program 相似文献
5.
Climate-change effects on extreme precipitation in central Europe: uncertainties of scenarios based on regional climate models 总被引:1,自引:0,他引:1
Observations as well as most climate model simulations are generally in accord with the hypothesis that the hydrologic cycle should intensify and become highly volatile with the greenhouse-gas-induced climate change, although uncertainties of these projections as well as the spatial and seasonal variability of the changes are much larger than for temperature extremes. In this study, we examine scenarios of changes in extreme precipitation events in 24 future climate runs of ten regional climate models, focusing on a specific area of the Czech Republic (central Europe) where complex orography and an interaction of other factors governing the occurrence of heavy precipitation events result in patterns that cannot be captured by global models. The peaks-over-threshold analysis with increasing threshold censoring is applied to estimate multi-year return levels of daily rainfall amounts. Uncertainties in scenarios of changes for the late 21st century related to the inter-model and within-ensemble variability and the use of the SRES-A2 and SRES-B2 greenhouse gas emission scenarios are evaluated. The results show that heavy precipitation events are likely to increase in severity in winter and (with less agreement among models) also in summer. The inter-model and intra-model variability and related uncertainties in the pattern and magnitude of the change is large, but the scenarios tend to agree with precipitation trends recently observed in the area, which may strengthen their credibility. In most scenario runs, the projected change in extreme precipitation in summer is of the opposite sign than a change in mean seasonal totals, the latter pointing towards generally drier conditions in summer. A combination of enhanced heavy precipitation amounts and reduced water infiltration capabilities of a dry soil may severely increase peak river discharges and flood-related risks in this region. 相似文献
6.
Barış Önol Deniz Bozkurt Ufuk Utku Turuncoglu Omer Lutfi Sen H. Nuzhet Dalfes 《Climate Dynamics》2014,42(7-8):1949-1965
In this study, human-induced climate change over the Eastern Mediterranean–Black Sea region has been analyzed for the twenty-first century by performing regional climate model simulations forced with large-scale fields from three different global circulation models (GCMs). Climate projections have been produced with Special Report on Emissions Scenarios A2, A1FI and B1 scenarios, which provide greater diversity in climate information for future period. The gradual increases for temperature are widely apparent during the twenty-first century for each scenario simulation, but ECHAM5-driven simulation generally has a weaker signal for all seasons compared to CCSM3 simulations except for the Fertile Crescent. The contrast in future temperature change between the winter and summer seasons is very strong for CCSM3-A2-driven and HadCM3-A2-driven simulations over Carpathians and Balkans, 4–5 °C. In addition, winter runoff over mountainous region of Turkey, which feeds many river systems including the Euphrates and Tigris, increases in second half of the century since the snowmelt process accelerates where the elevation is higher than 1,500 m. Moreover, analysis of daily temperature outputs reveals that the gradual decrease in daily minimum temperature variability for January during the twenty-first century is apparent over Carpathians and Balkans. Analysis of daily precipitation extremes shows that positive trend is clear during the last two decades of the twenty-first century over Carpathians for both CCSM3-driven and ECHAM5-driven simulations. Multiple-GCM driven regional climate simulations contribute to the quantification of the range of climate change over a region by performing detailed comparisons between the simulations. 相似文献
7.
《Global Environmental Change》1999,9(1):5-23
This paper outlines the effects of climate change by the 2050s on hydrological regimes at the continental scale in Europe, at a spatial resolution of 0.5×0.5°. Hydrological regimes are simulated using a macro-scale hydrological model, operating at a daily time step, and four climate change scenarios are used. There are differences between the four scenarios, but each indicates a general reduction in annual runoff in southern Europe (south of around 50°N), and an increase in the north. In maritime areas there is little difference in the timing of flows, but the range through the year tends to increase with lower flows during summer. The most significant changes in flow regime, however, occur where snowfall becomes less important due to higher temperatures, and therefore both winter runoff increases and spring flow decreases: these changes occur across a large part of eastern Europe. In western maritime Europe low flows reduce, but further east minimum flows will increase as flows during the present low flow season – winter – rise. “Drought” was indexed as the maximum total deficit volume below the flow exceeded 95% of the time: this was found to increase in intensity across most of western Europe, but decrease in the east and north. The study attempted to quantify several sources of uncertainty, and showed that the effects of model uncertainty on the estimated change in runoff were generally small compared to the differences between scenarios and the assumed change in global temperature by 2050. 相似文献
8.
We isolate the contribution of warming, other large-scale changes and soil moisture decline and feedbacks in driving future projected changes in daily precipitation across Europe. Our confidence in each of these mechanisms differs, so this analysis then allows us to determine an overall confidence (or reliability) in the projected changes. In winter, increases in extreme precipitation over Europe as a whole are judged to be reliable, dominated by increased atmospheric moisture with warming. At scales less than about 2,000 km changing circulation patterns could enhance or offset this increase. Additionally, over the Scandinavian mountains warming-induced circulation changes do offset the effect of increased moisture and the overall change is unreliable. In summer, increases in extreme precipitation over northern Scandinavia and decreases over the Mediterranean are reliable in the absence of considerable circulation change. Over central Europe, an increase in the proportion of summer rainfall falling as extreme events is reliable. 相似文献
9.
We present an analysis of climate change over Europe as simulated by a regional climate model (RCM) nested within time-slice atmospheric general circulation model (AGCM) experiments. Changes in mean and interannual variability are discussed for the 30-year period of 2071–2100 with respect to the present day period of 1961–1990 under forcing from the A2 and B2 IPCC emission scenarios. In both scenarios, the European region undergoes substantial warming in all seasons, in the range of 1–5.5°C, with the warming being 1–2°C lower in the B2 than in the A2 scenario. The spatial patterns of warming are similar in the two scenarios, with a maximum over eastern Europe in winter and over western and southern Europe in summer. The precipitation changes in the two scenarios also show similar spatial patterns. In winter, precipitation increases over most of Europe (except for the southern Mediterranean regions) due to increased storm activity and higher atmospheric water vapor loadings. In summer, a decrease in precipitation is found over most of western and southern Europe in response to a blocking-like anticyclonic circulation over the northeastern Atlantic which deflects summer storms northward. The precipitation changes in the intermediate seasons (spring and fall) are less pronounced than in winter and summer. Overall, the intensity of daily precipitation events predominantly increases, often also in regions where the mean precipitation decreases. Conversely the number of wet days decreases (leading to longer dry periods) except in the winter over western and central Europe. Cloudiness, snow cover and soil water content show predominant decreases, in many cases also in regions where precipitation increases. Interannual variability of both temperature and precipitation increases substantially in the summer and shows only small changes in the other seasons. A number of statistically significant regional trends are found throughout the scenario simulations, especially for temperature and for the A2 scenario. The results from the forcing AGCM simulations and the nested RCM simulations are generally consistent with each other at the broad scale. However, significant differences in the simulated surface climate changes are found between the two models in the summer, when local physics processes are more important. In addition, substantial fine scale detail in the RCM-produced change signal is found in response to local topographical and coastline features. 相似文献
10.
Daily output from the PRUDENCE ensemble of regional climate simulations for the end of the twentieth and twenty-first centuries over Europe is used to show that the increasing intensity of the most damaging summer heat waves over Central Europe is mostly due to higher base summer temperatures. In this context, base temperature is defined as the mean of the seasonal cycle component for those calendar days when regional heat waves occur and is close, albeit not identical, to the mean temperature for July–August. Although 36–47% of future Central Europe July and August days at the end of the twenty-first century are projected to be extreme according to the present day climatology, specific changes in deseasonalized heat wave anomalies are projected to be relatively small. Instead, changes in summer base temperatures appear much larger, clearly identifiable and of the same order of magnitude as changes in the whole magnitude of heat waves. Our results bear important consequences for the predictability of central European heat wave intensity under global warming conditions. 相似文献
11.
Changes in atmospheric circulation over Europe detected by objective and subjective methods 总被引:1,自引:0,他引:1
Summary Changes in atmospheric circulation over Europe since 1958 were examined using both objective (modes of low-frequency variability
and objective classification of circulation types) and subjective (Hess-Brezowsky classification of weather types) methods.
The analysis was performed with an emphasis on the differences between the winter (DJF) and summer (JJA) seasons, and between
objectively and subjectively based results. Majority of the most important changes in atmospheric circulation are same or
similar for the objective and subjective methods: they include the strengthening of the zonal flow in winter since the 1960s
to the early 1990s; the increase (decrease) in frequency of anticyclonic (cyclonic) types in winter from the late 1960s to
the early 1990s, with a subsequent decline (rise); and the sharp increase in the persistence (measured by the mean residence
time) of all groups of circulation types in winter around 1990 and of anticyclonic types in summer during the 1990s. Differences
between the findings obtained using the objective and subjective methods may result from the intrinsically different approach
to the classification (e.g. the Hess-Brezowsky weather types have a typical duration of at least 3 days while objective types
typically last 1–3 days). Generally, changes in atmospheric circulation which have taken place since the 1960s were more pronounced
in winter than in summer. The most conspicuous change seems to be the considerable increase in the persistence of circulation
types during the 1990s, which may be also reflected in the increase in the occurrence of climatic extremes observed in Europe
during recent years. 相似文献
12.
A. J. Coops 《Theoretical and Applied Climatology》1992,46(2-3):89-98
Summary A method is developed for analysing climate series. It is based on the assumption that climate undergoes abrupt changes by natural means. It is a generalization of an existing method for dividing a series into two parts. It is assumed that increasing concentrations of greenhouse gases will lead to a gradual climate change (trend) and that this change will be superimposed upon the natural abrupt changes (jumps). On the basis of these facts, jumps in the direction of a climate change resulting from the increased concentrations of greenhouse gases are expected to be stronger than those in the opposite direction and previous jumps in the same direction. Different criteria are used to support this assumption. The method of analysis is applied to time series of summer and winter temperatures of 13 European stations.The largest increases in temperature do not occur in the recent past; they occur around 1910 in winter and about 1930 in summer. As the test for detection of the enhanced greenhouse effect is made stricter, the assumption put forward becomes weaker. Most time series do not have significant trends within various sub-periods. Differences in variability between successive sub-periods are generally not significant. There is agreement between the results reported here and others in the literature. So far, there is no definite evidence that the increasing concentration of greenhouse gases is affecting the climate of Europe.With 6 Figures 相似文献
13.
Within the framework of the PMIP (Paleoclimate Modelling Intercomparison Project), we have compared mid-Holocene climate
simulations from 16 atmospheric general circulation models (AGCMs) with new pollen-based reconstructions of the European bioclimatic
variables for winter and growing season temperatures as well as annual water budget changes. In winter, some models are able
to simulate the reconstructed northeastern warming, due to an increased heat transport from the ocean, associated with a larger
north-south pressure gradient over the northern Atlantic. Whereas most models are only able to simulate a strong summer warming,
data indicate a shorter and/ or colder growing season in southern Europe and a longer and/or warmer growing season in northwestern
Europe. The reconstructed change in annual water budget indicates drier conditions in northwestern Europe and wetter conditions
in southern Europe. Some models simulate such moisture changes, due to more summer evaporation over Scandinavia during summer,
and more autumn-winter-spring precipitation over southern Europe. To address the PMIP approximation of no change in ocean
and land boundary conditions, we have performed short sensitivity experiments to surface boundary conditions (sea-surface-temperatures,
vegetation) using one single model. The model-data disagreements over Europe are probably due to the local influence of the
surrounding oceans which are not taken into account in the first PMIP simulations. We therefore stress the need for more mid-Holocene
SST reconstructions and further analysis of pollen data in the Mediterranean region.
Received: 23 February 1998 /Accepted: 19 September 1998 相似文献
14.
P. M. Della-Marta J. Luterbacher H. von Weissenfluh E. Xoplaki M. Brunet H. Wanner 《Climate Dynamics》2007,29(2-3):251-275
We investigate the large-scale forcing and teleconnections between atmospheric circulation (sea level pressure, SLP), sea
surface temperatures (SSTs), precipitation and heat wave events over western Europe using a new dataset of 54 daily maximum
temperature time series. Forty four of these time series have been homogenised at the daily timescale to ensure that the presence
of inhomogeneities has been minimised. The daily data have been used to create a seasonal index of the number of heat waves.
Using canonical correlation analysis (CCA), heat waves over western Europe are shown to be related to anomalous high pressure
over Scandinavia and central western Europe. Other forcing factors such as Atlantic SSTs and European precipitation, the later
as a proxy for soil moisture, a known factor in strengthening land–atmosphere feedback processes, are also important. The
strength of the relationship between summer SLP anomalies and heat waves is improved (from 35%) to account for around 46%
of its variability when summer Atlantic and Mediterranean SSTs and summer European precipitation anomalies are included as
predictors. This indicates that these predictors are not completely collinear rather that they each have some contribution
to accounting for summer heat wave variability. However, the simplicity and scale of the statistical analysis masks this complex
interaction between variables. There is some useful predictive skill of summer heat waves using multiple lagged predictors.
A CCA using preceding winter North Atlantic SSTs and preceding January to May Mediterranean total precipitation results in
significant hindcast (1972–2003) Spearman rank correlation skill scores up to 0.55 with an average skill score over the domain
equal to 0.28 ± 0.28. In agreement with previous studies focused on mean summer temperature, there appears to be some predictability
of heat wave events on the decadal scale from the Atlantic Multidecadal Oscillation (AMO), although the long-term global mean
temperature is also well related to western European heat waves. Combining these results with the observed positive trends
in summer continental European SLP, North Atlantic SSTs and indications of a decline in European summer precipitation then
possibly these long-term changes are also related to increased heat wave occurrence and it is important that the physical
processes controlling these changes be more fully understood. 相似文献
15.
Climate change might lead to large shifts in tourist flows, with large economic implications. This article simulates the effect
of future climate change by the 2080s on outdoor international tourism expenditure within Europe. The assessment is based
on the statistical relationship between bed nights and a climate-related index of human comfort, after accounting for other
determinants of bed nights such as income and prices. It is concluded that climate change could have significant impacts on
the regional distribution of the physical resources supporting tourism in Europe. For example, in summer, Southern Europe
could experience climate conditions that are less favourable to tourism than the current climate, while countries in the North
could enjoy better conditions. The economic effects of these changes are likely to be sizeable, albeit difficult to assess.
Crucially, they are shown to depend on tourists’ temporal flexibility with respect to holiday planning. The greater the prominence
of institutional rigidities such as school holidays, the larger the differences between winning and losing regions in terms
of economic impact. 相似文献
16.
Jan Kyselý Ladislav Gaál Romana Beranová Eva Plavcová 《Theoretical and Applied Climatology》2011,104(3-4):529-542
The study examines future scenarios of precipitation extremes over Central Europe in an ensemble of 12 regional climate model (RCM) simulations with the 25-km resolution, carried out within the European project ENSEMBLES. We apply the region-of-influence method as a pooling scheme when estimating distributions of extremes, which consists in incorporating data from a ‘region’ (set of gridboxes) when fitting an extreme value distribution in any single gridbox. The method reduces random variations in the estimates of parameters of the extreme value distribution that result from large spatial variability of heavy precipitation. Although spatial patterns differ among the models, most RCMs simulate increases in high quantiles of precipitation amounts when averaged over the area for the late-twenty-first century (2070–2099) climate in both winter and summer. The sign as well as the magnitude of the projected change vary only little for individual parts of the distribution of daily precipitation in winter. In summer, on the other hand, the projected changes increase with the quantile of the distribution in all RCMs, and they are negative (positive) for parts of the distribution below (above) the 98% quantile if averaged over the RCMs. The increases in precipitation extremes in summer are projected in spite of a pronounced drying in most RCMs. Although a rather general qualitative agreement of the models concerning the projected changes of precipitation extremes is found in both winter and summer, the uncertainties in climate change scenarios remain large and would likely further increase considerably if a more complete ensemble of RCM simulations driven by a larger suite of global models and with a range of possible scenarios of the radiative forcing is available. 相似文献
17.
Patrick Willems 《Climatic change》2013,120(4):931-944
Many studies have observed changes in the frequency and intensity of precipitation extremes and floods during the last decade(s). Natural variability by climate oscillations partly determines the observed evolution of precipitation extremes. Based on a technique for the identification and analysis of changes in extremes, this paper shows that precipitation extremes have oscillatory behaviour at multidecadal time scales. The analysis is based on a unique dataset of 108 years of 10-minute precipitation intensities at Uccle (Brussels), not affected by instrumental changes. We also checked the consistency of the findings with long precipitation records at 724 stations across Europe and the Middle East. The past 100 years show for northwestern Europe, both in winter and summer, larger and more precipitation extremes around the 1910s, 1950–1960s, and more recently during the 1990s–2000s. The oscillations for southwestern Europe are anti-correlated with these of northwestern Europe, thus with oscillation highs in the 1930–1940s and 1970s. The precipitation oscillation peaks are explained by persistence in atmospheric circulation patterns over the North Atlantic during periods of 10 to 15 years. 相似文献
18.
欧亚大陆夏季地表气温在近四十年有显著的升温趋势,本文基于ERA5再分析数据研究了1979~2019年间欧亚大陆不同区域的夏季地表气温的变化特征,并利用气候反馈响应分析方法揭示了各区域变暖原因的异同。作为全球海拔最高的大地形,青藏高原在过去四十年经历了显著的增温过程。青藏高原周边相对低海拔的地区(如北非—南欧地区、蒙古地区、东北亚地区)同样表现出明显的变暖特征,而高原南侧的南亚地区的地表气温却变化不明显。青藏高原夏季积雪融化引起的地表反照率减小使得更多短波辐射到达地表,放大高原地表增暖。北非—南欧地区增暖则主要源于大气气溶胶含量减少造成的入射短波辐射增加。同时,大气温度升高导致的向下长波辐射增强对北非—南欧地区以及蒙古地区的增暖都有显著贡献。此外,东北亚地区云的减少是造成其地表增暖最主要的过程,而南亚地区则是水汽增加和感热通量减少造成的增温与云和气溶胶增加造成的降温相抵消,因而温度变化幅度不大。 相似文献
19.
Aad van Ulden Geert Lenderink Bart van den Hurk Erik van Meijgaard 《Climatic change》2007,81(1):179-192
PRUDENCE simulations of the climate in Central Europe are analysed with respect to mean temperature, mean precipitation and three monthly mean geostrophic circulation indices. The three global models show important circulation biases in the control climate, in particular in the strength of the west-circulations in winter and summer. The nine regional models inherit much of the circulation biases from their host model, especially in winter. In summer, the regional models show a larger spread in circulation statistics, depending on nesting procedures and other model characteristics. Simulated circulation biases appear to have a significant inluence on simulated temperature and precipitation. The PRUDENCE ensemble appears to be biased towards warmer and wetter than observed circulations in winter, and towards warmer and dryer circulations in summer. A2-scenario simulations show important circulation changes, which have a significant impact on changes in the distributions of monthly mean temperature and precipitation. It is likely that interactions between land–surface processes and atmospheric circulation play an important role in the simulated changes in the summer climate in Central Europe. 相似文献
20.
Summary Climatic changes of summer temperature and precipitation in the greater Alpine region are assessed by using statistical-dynamical
downscaling. The downscaling procedure is applied to two 30-year periods (1971–2000 and 2071–2100, summer months only) taken
from the results of a transient coupled ocean/atmosphere climate scenario simulation with increasing greenhouse gas concentrations.
The downscaling results for the present-day climate are compared with observations. The estimated regional climate change
during the next 100 years shows a general warming. The mean summer temperatures increase by 3 to 5 Kelvin. The most intense
climatic warming is predicted in the western parts of the Alps. The amount of summer precipitation decreases in most parts
of central Europe by more than 20 percent. Increasing precipitation is simulated only over the Adriatic area and parts of
eastern central Europe.
The results are compared with observed climate trends for the last decades and results of other regional climate change estimations.
The observed trends and the majority of the simulated trends (including ours) have a number of common features. However, there
are also climate change estimates of other groups which completely contradict our results.
Received April 8, 1999 Revised November 16, 1999 相似文献