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1.
Assessments of the impacts of global change on carbon stocks in mountain regions have received little attention to date, in
spite of the considerable role of these areas for the global carbon cycle. We used the regional hydro-ecological simulation
system RHESSys in five case study catchments from different climatic zones in the European Alps to investigate the behavior
of the carbon cycle under changing climatic and land cover conditions derived from the SRES scenarios of the IPCC. The focus
of this study was on analyzing the differences in carbon cycling across various climatic zones of the Alps, and to explore
the differences between the impacts of various SRES scenarios (A1FI, A2, B1, B2), and between several global circulation models
(GCMs, i.e., HadCM3, CGCM2, CSIRO2, PCM). The simulation results indicate that the warming trend generally enhances carbon
sequestration in these catchments over the first half of the twenty-first century, particularly in forests just below treeline.
Thereafter, forests at low elevations increasingly release carbon as a consequence of the changed balance between growth and
respiration processes, resulting in a net carbon source at the catchment scale. Land cover changes have a strong modifying
effect on these climate-induced patterns. While the simulated temporal pattern of carbon cycling is qualitatively similar
across the five catchments, quantitative differences exist due to the regional differences of the climate and land cover scenarios,
with land cover exerting a stronger influence. The differences in the simulations with scenarios derived from several GCMs
under one SRES scenario are of the same magnitude as the differences between various SRES scenarios derived from one single
GCM, suggesting that the uncertainty in climate model projections needs to be narrowed before accurate impact assessments
under the various SRES scenarios can be made at the local to regional scale. We conclude that the carbon balance of the European
Alps is likely to shift strongly in the future, driven mainly by land cover changes, but also by changes of the climate. We
recommend that assessments of carbon cycling at regional to continental scales should make sure to adequately include sub-regional
differences of changes in climate and land cover, particularly in areas with a complex topography. 相似文献
2.
Kristina Blennow Mikael Andersson Johan Bergh Ola Sallnäs Erika Olofsson 《Climatic change》2010,99(1-2):261-278
We estimated how the possible changes in wind climate and state of the forest due to climate change may affect the probability of exceeding critical wind speeds expected to cause wind damage within a forest management unit located in Southern Sweden. The topography of the management unit was relatively gentle and the forests were dominated by Norway spruce (Picea abies (L.) Karst.). We incorporated a model relating the site index (SI) to the site productivity into the forest projection model FTM. Using estimated changes in the net primary production (NPP) due to climate change and assuming a relative change in NPP equal to a relative change in the site productivity, we simulated possible future states of the forest under gradual adjustment of SI in response to climate change. We estimated changes in NPP by combining the boreal-adapted BIOMASS model with four regional climate change scenarios calculated using the RCAO model for the period 2071–2100 and two control period scenarios for the period 1961–1990. The modified WINDA model was used to calculate the probability of wind damage for individual forest stands in simulated future states of the forest. The climate change scenarios used represent non-extreme projections on a 100-year time scale in terms of global mean warming. A 15–40% increase in NPP was estimated to result from climate change until the period 2071–2100. Increasing sensitivity of the forest to wind was indicated when the management rules of today were applied. A greater proportion of the calculated change in probability of wind damage was due to changes in wind climate than to changes in the sensitivity of the forest to wind. While regional climate scenarios based on the HadAM3H general circulation model (GCM) indicated no change (SRES A2 emission scenario) or a slightly reduced (SRES B2 emission scenario) probability of wind damage, scenarios based on the ECHAM4/OPYC3 GCM indicated increased probability of wind damage. The assessment should, however, be reviewed as the simulation of forest growth under climate change as well as climate change scenarios are refined. 相似文献
3.
W. N. Smith B. B. Grant R. L. Desjardins B. Qian J. Hutchinson S. Gameda 《Climatic change》2009,93(3-4):319-333
Under the threat of global warming it is important to determine the impact that future changes in climate may have on the environment and to what extent any adverse effects can be mitigated. In this study we assessed the impact that climate change scenarios may have on soil carbon stocks in Canada and examined the potential for agricultural management practices to improve or maintain soil quality. Historical weather data from 1951 to 2001 indicated that semi-arid soils in western Canada have become warmer and dryer and air temperatures have increased during the spring and winter months. Results from the Canadian Center for Climate Modelling and Analysis (CCCma) Coupled Global Climate Model (CGCM1,2) under two climate change forcing scenarios also indicated that future temperatures would increase more in the spring and winter. Precipitation increased significantly under the IPCC IS92a scenario and agreed with historical trends in eastern Canada whereas the IPCC SRES B2 scenario indicated very little change in precipitation and better matched historical trends in western Canada. The Century model was used to examine the influence of climate change on agricultural soil carbon (C) stocks in Canada. Relative to simulations using historical weather data, model results under the SRES B2 climate scenario indicated that agricultural soils would lose 160 Tg of carbon by 2099 and under the IS92a scenario would lose 53 Tg C. Carbon was still lost from soils in humid climatic regions even though C inputs from crops increased by 10–13%. Carbon factors associated with changes in management practices were also estimated under both climate change scenarios. There was little difference in factors associated with conversion from conventional to no-till agriculture, while carbon factors associated with the conversion of annual crops to perennial grass were lower than for historical data in semi-arid soils because water stress hampered crop production but were higher in humid soils. 相似文献
4.
Impacts of Climate Change on the Global Forest Sector 总被引:1,自引:0,他引:1
John Perez-Garcia Linda A. Joyce A. David Mcguire Xiangming Xiao 《Climatic change》2002,54(4):439-461
The path and magnitude of future anthropogenic emissions of carbon dioxide will likely influence changes in climate that may impact the global forest sector. These responses in the global forest sector may have implications for international efforts to stabilize the atmospheric concentration of carbon dioxide. This study takes a step toward including the role of global forest sector in integrated assessments of the global carbon cycle by linking global models of climate dynamics, ecosystem processes and forest economics to assess the potential responses of the global forest sector to different levels of greenhouse gas emissions. We utilize three climate scenarios and two economic scenarios to represent a range of greenhouse gas emissions and economic behavior. At the end of the analysis period (2040), the potential responses in regional forest growing stock simulated by the global ecosystem model range from decreases and increases for the low emissions climate scenario to increases in all regions for the high emissions climate scenario. The changes in vegetation are used to adjust timber supply in the softwood and hardwood sectors of the economic model. In general, the global changes in welfare are positive, but small across all scenarios. At the regional level, the changes in welfare can be large and either negative or positive. Markets and trade in forest products play important roles in whether a region realizes any gains associated with climate change. In general, regions with the lowest wood fiber production cost are able to expand harvests. Trade in forest products leads to lower prices elsewhere. The low-cost regions expand market shares and force higher-cost regions to decrease their harvests. Trade produces different economic gains and losses across the globe even though, globally, economic welfare increases. The results of this study indicate that assumptions within alternative climate scenarios and about trade in forest products are important factors that strongly influence the effects of climate change on the global forest sector. 相似文献
5.
两种气候变化情景下中国未来的粮食供给 总被引:4,自引:0,他引:4
全球温室气体排放导致的全球温度的上升一直是国际社会关注的重点问题之一。利用IPCC(政府间气候变化专门委员会)SRES(排放情景特别报告)的A2(中-高)和B2(中-低)温室气体排放情景,结合区域气候模式PRECIS和CERES作物模型模拟和分析了未来不同的温室气体排放情景下,中国未来2020年、2050年和2080年各个时段粮食的供需情景,并结合未来社会经济的发展分析了气候变化对未来粮食供求的影响,探讨了不同的气候变化程度对未来中国粮食供应的影响。结果表明:如果不考虑CO2的肥效作用,未来我国三种主要粮食作物(小麦、水稻和玉米)均以减产为主,灌溉可以部分地减少减产幅度,如果单考虑CO2的肥效作用,三种作物的产量变化以增产为主。若保持959/6的粮食自给率,人口按照SRESA2和B2情景增长,到2030年的技术进步可使粮食年单产递增0.79/6以上,维持目前的种植比例和种植面积,B2情景下,气候变化对我国的粮食安全问题将不会构成威胁,而A2情景下,气候变化将会对我国可持续发展的粮食安全造成威胁。 相似文献
6.
黑龙江省未来41年气候变化趋势与突变分析 总被引:1,自引:0,他引:1
选用由英国Hadley中心区域气候模式系统PRECIS构建的基准时段(1961—1990年)和未来时段(2010--2050年)A2、B2情景气候数据,应用线性倾向估算法、累积距平及Mann—Kendall法对排放情景特别报告(SRES)中A2和B2情景下黑龙江省2010--2050年的平均气温、平均最高最低气温、降水量的变化趋势和突变进行了分析。结果表明:相对于基准气候(1961--1990年),未来41a平均气温表现出明显的上升趋势,A2、B2情景下年均气温分别升高1.63℃和1.94℃,突变分别发生在2031年和2033年;相对于基准气候,A2、B2情景下未来41a降水量分别增加5.3%和1.1%,降水量变化趋势不同,A2情景下为4.03mm/10a,B2情景下为5.94mm/10a,但趋势均不显著,且没有突变发生。总体上,黑龙江省未来41a的气候为向暖湿变化的趋势。 相似文献
7.
利用5个全球气候模式和中国东北地区162个站点地面温度实测资料,评估全球气候模式和多模式集合平均对中国东北地区地面温度的模拟能力,并对SRES B1、A1B和A2排放情景下,中国东北地区未来地面温度变化进行预估。结果表明:全球气候模式能够较好地再现了东北地区地面温度的年变化和空间分布特征,但存在系统性冷偏差,模式对夏季地面温度模拟偏低1.16 ℃,优于冬季。预估结果表明,3种排放情景下21世纪中期和末期东北地区地面温度均将升高,末期增幅高于中期,冬季增幅高于其他季节, SRES A2排放情景下增幅最大,B1排放情景下最小;增温幅度自南向北逐渐增大,增温最显著地区位于黑龙江小兴安岭;21世纪末期3种情景下中国东北地区年平均地面温度将分别升高2.39 ℃(SRES B1)、3.62 ℃(SRES A1B)和4.43 ℃(SRES A2)。 相似文献
8.
Juan Ignacio L??pez-Moreno S. Goyette S. M. Vicente-Serrano M. Beniston 《Climatic change》2011,105(3-4):489-508
The intensity and frequency of heavy snowfall events in the Pyrenees were simulated using data from the HIRHAM regional climate model for a control period (1960?C1990) and two greenhouse emission scenarios (SRES B2 and A2) for the end of the twenty-first century (2070?C2100). Comparisons between future and control simulations enabled a quantification of the expected change in the intensity and frequency of these events at elevations of 1,000, 1,500, 2,000 and 2,500?m a.s.l. The projected changes in heavy snowfall depended largely on the elevation and the greenhouse gas emission scenario considered. At 1,000?m a.s.l., a marked decrease in the frequency and intensity of heavy snowfall events was projected with the B2 and A2 scenarios. At 1,500?m a.s.l., a decrease in the frequency and intensity is only expected under the higher greenhouse gas emission scenario (A2). Above 2,000?m a.s.l., no change or heavier snowfalls are expected under both emission scenarios. Large spatial variability in the impacts of climate change on heavy snowfall events was found across the study area. 相似文献
9.
Assessing the strength of regional changes in near-surface climate associated with a global warming of 2°C 总被引:2,自引:1,他引:1
Wilhelm May 《Climatic change》2012,110(3-4):619-644
In this study, the strength of the regional changes in near-surface climate associated with a global warming of 2°C with respect to pre-industrial times is assessed, distinguishing between 26 different regions. Also, the strength of these regional climate changes is compared to the strength of the respective changes associated with a markedly stronger global warming of 4.5°C. The magnitude of the regional changes in climate is estimated by means of a normalized regional climate change index, which considers changes in the mean as well as changes in the interannual variability of both near-surface temperature and precipitation. The study is based on two sets of four ensemble simulations with the ECHAM5/MPI-OM coupled climate model, each starting from different initial conditions. In one set of simulations (1860–2200), the greenhouse gas concentrations and sulphate aerosol load have been prescribed according to observations until 2000 and according to the SRES A1B scenario after 2000. In the other set of simulations (2020–2200), the greenhouse gas concentrations and sulphate aerosol load have been prescribed in such a way that the simulated global warming does not exceed 2°C with respect to pre-industrial times. The study reveals the strongest changes in near-surface climate in the same regions for both scenarios, i.e., the Sahara, Northern Australia, Southern Australia and Amazonia. The regions with the weakest changes in near-surface climate, on the other hand, vary somewhat between the two scenarios except for Western North America and Southern South America, where both scenarios show rather weak changes. The comparison between the magnitude of the regional changes in near-surface climate for the two scenarios reveals relatively strong changes in the 2°C-stabilization scenario at high northern latitudes, i.e., Northeastern Europe, Alaska and Greenland, and in Amazonia. Relatively weak regional climate changes in this scenario, on the other hand, are found for Eastern Asia, Central America, Central South America and Southern South America. The ratios between the regional changes in the near-surface climate for the two scenarios vary considerably between different regions. This illustrates a limitation of obtaining regional changes in near-surface climate associated with a particular scenario by means of scaling the regional changes obtained from a widely used “standard” scenario with the ratio of the changes in the global mean temperature projected by these two scenarios. 相似文献
10.
Climate change impacts on water management and irrigated agriculture in the Yakima River Basin, Washington, USA 总被引:1,自引:0,他引:1
Julie A. Vano Michael J. Scott Nathalie Voisin Claudio O. Stöckle Alan F. Hamlet Kristian E. B. Mickelson Marketa McGuire Elsner Dennis P. Lettenmaier 《Climatic change》2010,102(1-2):287-317
The Yakima River Reservoir system supplies water to ~180,000 irrigated hectares through the operation of five reservoirs with cumulative storage of ~30% mean annual river flow. Runoff is derived mostly from winter precipitation in the Cascade Mountains, much of which is stored as snowpack. Climate change is expected to result in earlier snowmelt runoff and reduced summer flows. Effects of these changes on irrigated agriculture were simulated using a reservoir system model coupled to a hydrological model driven by downscaled scenarios from 20 climate models archived by the 2007 Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment Report. We find earlier snowmelt results in increased water delivery curtailments. Historically, the basin experienced substantial water shortages in 14% of years. Without adaptations, for IPCC A1B global emission scenarios, water shortages increase to 27% (13% to 49% range) in the 2020s, to 33% in the 2040s, and 68% in the 2080s. For IPCC B1 emissions scenarios, shortages occur in 24% (7% to 54%) of years in the 2020s, 31% in the 2040s and 43% in the 2080s. Historically unprecedented conditions where senior water rights holders suffer shortfalls occur with increasing frequency in both A1B and B1 scenarios. Economic losses include expected annual production declines of 5%–16%, with greater probabilities of operating losses for junior water rights holders. 相似文献
11.
The ability of seven global coupled ocean-atmosphere models to reproduce East Asian monthly surface temperature and precipitation climatologies during 1961 1990 is evaluated. January and July climate differences during the 2050s and 2090s relative to 1961-1990 projected by the seven-model ensemble under the Special Report on Emission Scenarios (SRES) A2 and B2 scenarios are then briefly discussed. These projections, together with the corresponding atmospheric CO2 concentrations under the SRES A2 and B2 scenarios, are subsequently used to drive the biome model BIOME3 to simulate potential vegetation distribution in China during the 2050s and 2090s. It is revealed that potential vegetation belts during the 2050s shift northward greatly in central and eastern China compared to those during 1961-1990. In contrast, potential vegetation change is slight in western China on the whole. The spatial pattern of potential vegetation during the 2090s is generally similar to that during the 2050s, but the range of potential vegetation change against 1961 1990 is more extensive during the 2090s than the 2050s, particularly in western China. Additionally, there exists model-dependent uncertainty of potential vegetation change under the SRES A2 scenario during the 2090s, which is due to the scatter of projected climate change by the models. The projected change in potential vegetation under the SRES A2 scenario during the 2090s is attributable to surface temperature change south of 35°N and to the joint changes of surface temperature, precipitation, and atmospheric CO2 concentration north of 35°N. 相似文献
12.
Potential climate change effects on warm-season livestock production in the Great Plains 总被引:1,自引:0,他引:1
Terry L. Mader Katrina L. Frank John A. Harrington Jr. G. Leroy Hahn John A. Nienaber 《Climatic change》2009,97(3-4):529-541
Projected production responses were derived for confined swine and beef and for milk-producing dairy cattle based on climate change projections in daily ambient temperature. Milk production from dairy cattle and the number of days to grow swine and beef cattle were simulated. Values were obtained for three central United States transects and three climate scenarios which were based on projected mean daily ambient temperatures associated with a baseline, doubling, and tripling of atmospheric greenhouse gas (CO2) levels for the period June 1 to October 31. For swine, a slight northwest to southeast gradient is evident. Transect 1 (west side) shows no losses under the doubling scenario and losses up to 22.4% under the tripling scenario. Transect 3 (east side) displays losses of over 70% under the tripling scenario. For beef, positive benefits were simulated in Transect 1 with increasing temperatures, although a northwest to southeast gradient was also evident. For dairy, no positive benefits in milk production were found due to climate effects. Projected production declines ranged from 1% to 7.2%, depending on location. However, ranges in predicted differences were less than those simulated for beef and swine. These simulations suggest regional differences in animal production due to climate change will be apparent. For small changes in climate conditions, animals will likely be able to adapt, while larger changes in climate conditions will likely dictate that management strategies be implemented. Exploration of the effects of climate changes on livestock should allow producers to adjust management strategies to reduce potential impact and economic losses due to environmental changes. 相似文献
13.
Climate changes, associated with accumulation of greenhouse gases, are expected to have a profound influence on agricultural
sustainability in Israel, a semi-arid area characterized by a cold wet winter and a dry warm summer. Accordingly this study
explored economic aspects of agricultural production under projected climate-change scenarios by the “production function”
approach, as applied to two representative crops: wheat, as the major crop grown in Israel’s dry southern region, and cotton,
representing the more humid climate in the north. Adjusting outputs of the global climate model HadCM3 to the specific research
locations, we generated projections for 2070–2100 temperatures and precipitations for two climate change scenarios. Results
for wheat vary among climate scenarios; net revenues become negative under the severe scenario (change from −145 to −273%),
but may increase under the moderate one (−43 to +35%), depending on nitrogen applied to the crop. Distribution of rain events
was found to play a major role in determining yields. By contrast, under both scenarios cotton experiences a considerable
decrease in yield with significant economic losses (−240 and −173% in A2 and B2 scenarios, respectively). Additional irrigation
and nitrogen may reduce farming losses, unlike changes in seeding dates. 相似文献
14.
This paper evaluates the role of trade as a mechanism of economic adjustment to the impacts of climate change on agriculture.
The study uses a model of the world economy able to reflect changes in comparative advantage; the model is used to test the
hypotheses that trade can assure that, first, satisfying global agricultural demand will not be jeopardized, and, second,
general access to food will not decrease. The hypotheses are tested for three alternative scenarios of climate change; under
each scenario, regions adjust to the climatic assumptions by changing the land areas devoted to agriculture and the mix of
agricultural goods produced, two of the major mechanisms of agricultural adaptation. We find that trade makes it possible
to satisfy the world demand for agricultural goods under the changed physical conditions. However, access to food decreases
in some regions of the world. Other patterns also emerge that indicate areas of concern in relying on trade as a mechanism
for the adjustment of agriculture to likely future changes in climate. 相似文献
15.
M. A. Esteve-Selma J. Martínez-Fernández I. Hernández-García J. P. Montávez J. J. López-Hernández J. F. Calvo 《Climatic change》2012,113(3-4):663-678
South-eastern Spain is a key area for assessing the effects of climate change on biodiversity since it presents an ecotone between the Mediterranean biome and the subtropical shrublands of arid lands. The forests of Tetraclinis articulata constitutes an especially relevant case. A species distribution model has been developed, regionalised climate change scenarios for South-eastern Spain were generated and expected changes in the suitability area of this species were estimated under B2 and A2 SRES scenarios for the time slice 2020–2050. Moreover, land use in the present and future potential habitat has been analysed. The high sensitivity of T. articulata is expressed not only as effects of climate change in the near future when compared to the present-day situation but also in the remarkable differences under scenarios B2 and A2. Under scenario B2 the suitable area for T. articulata would expand six-fold whereas under A2 the potential habitat would disappear from its present-day distribution and would move to a small area in the interior mountains. Under scenario B2 the future potential habitat in the coastal location would include enough area of shrublands, the main effective habitat of the species. Moreover, the present and future potential habitat partially overlaps, which facilitates the species migration. On the contrary, in the interior potential habitat the land use is less favourable for the effective habitat, the actual and future potential habitat do not overlap and the low dispersal capabilities of the species prevents natural migration to the interior to be expected. 相似文献
16.
The climate change research community’s shared socioeconomic pathways (SSPs) are a set of alternative global development scenarios focused on mitigation of and adaptation to climate change. To use these scenarios as a global context that is relevant for policy guidance at regional and national levels, they have to be connected to an exploration of drivers and challenges informed by regional expertise.In this paper, we present scenarios for West Africa developed by regional stakeholders and quantified using two global economic models, GLOBIOM and IMPACT, in interaction with stakeholder-generated narratives and scenario trends and SSP assumptions. We present this process as an example of linking comparable scenarios across levels to increase coherence with global contexts, while presenting insights about the future of agriculture and food security under a range of future drivers including climate change.In these scenarios, strong economic development increases food security and agricultural development. The latter increases crop and livestock productivity leading to an expansion of agricultural area within the region while reducing the land expansion burden elsewhere. In the context of a global economy, West Africa remains a large consumer and producer of a selection of commodities. However, the growth in population coupled with rising incomes leads to increases in the region’s imports. For West Africa, climate change is projected to have negative effects on both crop yields and grassland productivity, and a lack of investment may exacerbate these effects. Linking multi-stakeholder regional scenarios to the global SSPs ensures scenarios that are regionally appropriate and useful for policy development as evidenced in the case study, while allowing for a critical link to global contexts. 相似文献
17.
Climatic changes associated with a global “2°C-stabilization” scenario simulated by the ECHAM5/MPI-OM coupled climate model 总被引:1,自引:0,他引:1
Wilhelm May 《Climate Dynamics》2008,31(2-3):283-313
In this study, concentrations of the well-mixed greenhouse gases as well as the anthropogenic sulphate aerosol load and stratospheric ozone concentrations are prescribed to the ECHAM5/MPI-OM coupled climate model so that the simulated global warming does not exceed 2°C relative to pre-industrial times. The climatic changes associated with this so-called “2°C-stabilization” scenario are assessed in further detail, considering a variety of meteorological and oceanic variables. The climatic changes associated with such a relatively weak climate forcing supplement the recently published fourth assessment report by the IPCC in that such a stabilization scenario can only be achieved by mitigation initiatives. Also, the impact of the anthropogenic sulphate aerosol load and stratospheric ozone concentrations on the simulated climatic changes is investigated. For this particular climate model, the 2°C-stabilization scenario is characterized by the following atmospheric concentrations of the well-mixed greenhouse gases: 418 ppm (CO2), 2,026 ppb (CH4), and 331 ppb (N2O), 786 ppt (CFC-11) and 486 ppt (CFC-12), respectively. These greenhouse gas concentrations correspond to those for 2020 according to the SRES A1B scenario. At the same time, the anthropogenic sulphate aerosol load and stratospheric ozone concentrations are changed to the level in 2100 (again, according to the SRES A1B scenario), with a global anthropogenic sulphur dioxide emission of 28 TgS/year leading to a global anthropogenic sulphate aerosol load of 0.23 TgS. The future changes in climate associated with the 2°C-stabilization scenario show many of the typical features of other climate change scenarios, including those associated with stronger climatic forcings. That are a pronounced warming, particularly at high latitudes accompanied by a marked reduction of the sea-ice cover, a substantial increase in precipitation in the tropics as well as at mid- and high latitudes in both hemispheres but a marked reduction in the subtropics, a significant strengthening of the meridional temperature gradient between the tropical upper troposphere and the lower stratosphere in the extratropics accompanied by a pronounced intensification of the westerly winds in the lower stratosphere, and a strengthening of the westerly winds in the Southern Hemisphere extratropics throughout the troposphere. The magnitudes of these changes, however, are somewhat weaker than for the scenarios associated with stronger global warming due to stronger climatic forcings, such as the SRES A1B scenario. Some of the climatic changes associated with the 2°C-stabilization are relatively strong with respect to the magnitude of the simulated global warming, i.e., the pronounced warming and sea-ice reduction in the Arctic region, the strengthening of the meridional temperature gradient at the northern high latitudes and the general increase in precipitation. Other climatic changes, i.e., the El Niño like warming pattern in the tropical Pacific Ocean and the corresponding changes in the distribution of precipitation in the tropics and in the Southern Oscillation, are not as markedly pronounced as for the scenarios with a stronger global warming. A higher anthropogenic sulphate aerosol load (for 2030 as compared to the level in 2100 according to the SRES A1B scenario) generally weakens the future changes in climate, particularly for precipitation. The most pronounced effects occur in the Northern Hemisphere and in the tropics, where also the main sources of anthropogenic sulphate aerosols are located. 相似文献
18.
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
19.
Climate change and critical thresholds in China’s food security 总被引:2,自引:0,他引:2
Identification of ‘critical thresholds’ of temperature increase is an essential task for inform policy decisions on establishing
greenhouse gas (GHG) emission targets. We use the A2 (medium-high GHG emission pathway) and B2 (medium-low) climate change
scenarios produced by the Regional Climate Model PRECIS, the crop model – CERES, and socio-economic scenarios described by
IPCC SRES, to simulate the average yield changes per hectare of three main grain crops (rice, wheat, and maize) at 50 km ×
50 km scale. The threshold of food production to temperature increases was analyzed based on the relationship between yield
changes and temperature rise, and then food security was discussed corresponding to each IPCC SRES scenario. The results show
that without the CO2 fertilization effect in the analysis, the yield per hectare for the three crops would fall consistently as temperature rises
beyond 2.5 ^C; when the CO2 fertilization effect was included in the simulation, there were no adverse impacts on China’s food production under the projected
range of temperature rise (0.9–3.9 ^C). A critical threshold of temperature increase was not found for food production. When the socio-economic scenarios, agricultural
technology development and international trade were incorporated in the analysis, China’s internal food production would meet
a critical threshold of basic demand (300 kg/capita) while it would not under A2 (no CO2 fertilization); whereas basic food demand would be satisfied under both A2 and B2, and would even meet a higher food demand
threshold required to sustain economic growth (400 kg/capita) under B2, when CO2 fertilization was considered. 相似文献
20.
5个IPCC AR4全球气候模式对东北三省降水模拟与预估 总被引:3,自引:0,他引:3
利用IPCC AR4中5个全球气候模式数据集和中国东北三省162个站降水实测资料,评估5个全球气候模式和多模式集合平均对中国东北三省降水的模拟能力,并对SRES B1、A1B和A2三种排放情景东北三省未来降水变化进行预估。结果表明:全球气候模式能较好再现东北三省降水的月变化,但存在系统性湿偏差;多模式集合平均能较好模拟东北三省年降水量的空间分布,但模拟中心偏北,强度略强,模式对东北三省夏季降水的模拟效果优于冬季降水;预估结果表明,三种排放情景下21世纪中前期和末期东北三省降水均将增多,21世纪末期增幅高于21世纪中前期,冬季增幅高于其他季节;就排放情景而言,SRES A1B和A2排放情景增幅相当,高于B1排放情景增幅;不同排放情景东北三省降水量增率分布呈较一致变化,A2排放情景下,增幅最显著的辽宁环渤海地区年降水量在21世纪中前期将增加7%以上,21世纪末期将增加16%。 相似文献