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1.
利用MM5V3区域气候模式单向嵌套ECHAM5全球环流模式,对中国地区1978-2000年及IPCC A1B情景下2038-2070年气候分别进行了水平分辨率为50 km的模拟试验.文章首先检验了模式模拟的当代极端气候结果,在此基础上对6个极端温度指数和6个极端降水指数的未来变化进行了预估.检验结果表明:MM5V3模式对中国地区当代日最高、最低温度及强降水(大雨和暴雨)日数的空间分布和概率特征均具有一定的模拟能力,但模拟的日最高温度在大部分地区偏低,日最低温度在南方地区偏低、西北地区偏高.概率统计结果显示日最高温度向低值频段偏移,日最低温度在0℃的峰值附近明显偏高.模式对大雨和暴雨年平均日数的模拟在东部地区偏多,概率统计结果则为一致偏大.未来中国地区极端气候预估结果表明:极端高温、极端低温和相对高温在全国范围内都将升高,且线性趋势均为上升;霜日日数则为减少,并具有下降趋势;暖日日数和相对低温在青藏高原和新疆部分地区有所减少、其它地区均为增加,且线性趋势暖日日数为上升,相对低温不明显.极端降水指数的变化具有区域特征,其中单日最大降水、连续五日最大降水、最长无雨期、强降水日数、简单降水强度和极端降水总量均在江淮、华南及西南地区有所增多,而在东北及内蒙古地区有所减少,未来中国南方地区降水的极端化趋势将更加显著.极端降水指数的线性趋势除最长无雨期外其它均为上升. 相似文献
2.
采用政府间气候变化委员会资料中心的模式预测结果,本文分析了SRES A2温室气体和气溶胶排放情景下中国大陆21世纪前30年的10年际气候变化趋势. 研究揭示:大陆冬季和夏季表面温度、表面最高温度和最低温度分别升高0.3~2.3℃、0.1~2.0℃、0.5~2.7℃,增幅大体上呈现东西向带状分布,由南至北升温逐渐加强,且增幅随时间加大. 此外,上述三气候要素冬季升温幅度要大于同期夏季、表面最低温度升幅要强于同期表面最高温度,冬季和夏季表面温度的季节内变化范围减小. 冬季东亚地区海平面气压异常幅度在-1.0hPa至0.4hPa之间变化,呈东西向带状分布,表现为南正北负、随时间推进异常幅度有所加大,正负交界面向南扩展;同时,东北、华北和西部海平面气压负异常较大. 夏季海平面气压异常空间分布与冬季相似. 2001~2030年,青藏高原大部、大陆东南部和河套大部分地区降水量增加0.1~0.8mm/d. 相似文献
3.
在最新的SRES A2和B2温室气体排放情景下,利用国际上7个气候模式针对未来全球变暖的数值模拟结果,本文着重分析了东亚区域气候21世纪的变化趋势. 研究揭示:中国大陆年均表面气温升高过程与全球同步,但增幅在东北、西部和华中地区较大,且表现出明显的年际变化;全球年均表面气温增幅纬向上大体呈带状分布,两极地区最为明显,并在北极地区达到最大;此外,21世纪后半段北半球高纬度地区的年平均强升温幅度主要来自于冬季增温. 在21世纪前50年,温室气体含量的增加除在一定程度上会增加青藏高原大部分夏季降水量外,不会对中国大陆其余地区的年、季节平均降水量产生较大影响;但持续的温室气体含量增加将最终导致大陆降水量几乎是全域性的增加. 相似文献
4.
本文以北京气象站长期地面气温观测资料为例,发展了一种无早期参考序列条件下城镇站城市化偏差评价和订正方法.首先对北京站逐月平均最高、最低气温资料进行质量控制和均一化处理,并借助卫星遥感亮度温度资料遴选附近乡村站;然后利用最近3年逐时地面气温资料,计算观象台和5个乡村站各月平均地面气温的差值,把其作为北京站1915-2012年期间的城市化累积影响;最后假设城市化累积影响在整个研究时期呈匀速增长,采用线性订正法对地面月平均气温序列中的城市化偏差进行订正.分析表明:资料均一化处理后,北京站近百年最高、最低和平均气温多年平均值有所下降,气温日较差则有所提高,但三种年平均气温序列增温趋势和年平均气温日较差序列下降趋势有所增强.北京站年平均最低气温、平均气温和气温日较差序列中均存在较大的城市化累积影响,其中最低气温和平均气温四个季节均为正值,冬季最大,秋季次之,夏季最小,四季和年平均气温日较差均为较大的负值.订正城市化偏差后,最低气温和平均气温增加速率均明显下降,年平均气温日较差下降趋势则明显变弱. 相似文献
5.
采用高水平分辨率区域气候模式进行区域未来气候变化预估,对理解全球增暖对区域气候的潜在影响和科学评估区域气候变化有很好的参考价值.这里对国家气候中心使用25 km高水平分辨率区域气候模式RegCM3单向嵌套全球模式MIROC3.2_hires在观测温室气体(1951—2000)和IPCC A1B温室气体排放情景下(2001—2100)进行的共计150年长时间模拟结果,进行华北地区未来气温、降水和极端气候事件变化的分析.模式检验结果表明:模式对当代(1981—2000)气温以及和气温有关的极端气候事件(霜冻日数、生长季长度)的空间分布和数值模拟较好;对降水及和降水有关的极端气候事件(强降水日期、降水强度、五日最大降水量)能够模拟出它们各自的主要空间分布特征,但在模拟数值上存在偏大、偏强的误差.和全球模式驱动场相比,区域模式模拟的气温、降水和极端气候事件有明显的改进.2010—2100年华北地区随时间区域平均气温升高幅度逐渐增大,随之霜冻日数逐渐减少,生长季长度逐渐增多;同时随温室效应的不断加剧,未来降水呈增加的趋势,强降水日期和五日最大降水量逐渐增多、降水强度逐渐增大.从空间分布看,21世纪末期(2081—2100)气温、降水以及有关的极端气候事件变化比21世纪中期(2041—2060)更加明显. 相似文献
6.
中国当代土地利用对区域气候影响的数值模拟 总被引:20,自引:0,他引:20
使用RegCM3区域气候模式,嵌套欧洲数值预报中心(ECMWF)ERA40再分析资料,分别进行了中国区域在实际植被和理想植被分布情况下各15年时间长度(1987-2001)的积分试验,以研究我国土地利用状况对气候的影响。通过两个试验结果的对比,研究了我国土地利用状况对气候的影响。分析主要集中于气温、降水等的变化上,并对结果进行了统计显著性检验。结果表明,当代土地利用/植被覆盖变化加强了中国地区冬、夏季的季风环流,同时改变了地表能量平衡状况,从而对各气候要素产生重要影响。冬季,植被改变引起长江以南降水减少、气温降低,长江以北降水增加。夏季,植被改变显著影响了南方地区的气候,使得这里降水增多,黄淮、江淮气温降低,华南气温上升;同时引起中国北方降水减少,气温在西北部分植被退化地区升高。植被变化对日最低、最高气温的影响更大。总体来说,土地利用引起了年平均降水在南方增加、北方减少,年平均气温在南方显著降低。 相似文献
7.
基于24个CMIP5全球耦合模式模拟结果,分析了中国区域年平均降水和ETCCDI强降水量(R95p)、极端强降水量(R99p)对增暖的响应.定量分析结果显示,CMIP5集合模拟的当代中国区域平均降水对增温的响应较观测偏弱,而极端降水的响应则偏强.对各子区域气温与平均降水、极端降水的关系均有一定的模拟能力,并且极端降水的模拟好于平均降水.RCP4.5和RCP8.5情景下,随着气温的升高,中国区域平均降水和极端降水均呈现一致增加的趋势,中国区域平均气温每升高1℃,平均降水增加的百分率分别为3.5%和2.4%,R95p增加百分率为11.9%和11.0%,R99p更加敏感,分别增加21.6%和22.4%.就各分区来看,当代的区域性差异较大,未来则普遍增强,并且区域性差异减小,在持续增暖背景下,中国及各分区极端降水对增暖的响应比平均降水更强,并且越强的极端降水敏感性越大.未来北方地区平均降水对增暖的响应比南方地区的要大,青藏高原和西南地区的R95p和R99p增加最显著,表明未来这些区域发生暴雨和洪涝的风险将增大. 相似文献
8.
中国日极端降水和趋势 总被引:1,自引:0,他引:1
《中国科学:地球科学》2017,(12)
利用中国2000多站50年以上的日降水资料,提取各站6个极端降水指数,即历年最大值(top-1)、历年10个最大值(top-10)累积量、历年总降水量、历年夏季top-1、历年夏季top-10累积量、历年夏季总降水量,分别形成各站各极端降水指数时间序列.统计了历年全国及6个子区域整个研究资料时段内出现top-1和top-10值的总站次,分别形成历年全国及6个子区域极端降水总站次时间序列.各极端降水指数时间序列的趋势分析表明,中国各站top-1和top-10累积量时间序列趋势分布存在较为一致的3个明显趋势区域,即中国东南正趋势区、西北正趋势区和华北负趋势区,但各时间序列的趋势分布区域特征和趋势幅度增减程度不尽相同;正负趋势明显地区的大多数站点趋势增(减)幅度比(趋势幅度与平均值的比值)达10~30%,部分站点达30%以上.top-1和top-10降水全国年总站次时间序列表明了一致的线性增加趋势,平均每十年分别增加2.4站和15站,但年际差别较大;极端降水年总站次表现为三段极端降水多发期,分别出现在20世纪60年代初、90年代中后期和21世纪初,6个区域极端降水年总站次趋势特征与全国年总站次不尽相同,极端降水全国年总站次出现较多的年份在区域上表现不一样.与降水有关的环流形势要素的时间序列趋势分析表明,华北及上游蒙古高原地区呈现明显的位势高度增加趋势,而低层从中国南部沿海地区到华北地区呈现一条南风风速减弱的趋势带和华北地区水汽含量减少的趋势区,这些趋势特征有利于华北地区极端降水的减少.经验回归水平分析表明,50年一遇重现水平从南部沿海的400~600mm减少到西北地区的50mm以下,相比20年一遇重现水平提升率平均达6.8%,但比降水最大值可小一倍以上. 相似文献
9.
使用全球海气耦合模式和区域气候模式,对人类活动影响导致的温室气体和气溶胶增加引起的长江中下游地区的气候变化进行了分析研究.全球模式部分使用的是IPCC数据分发中心提供的5个模式模拟结果,包括IS92a中未来温室气体增加(GG)以及温室气体和硫化物气溶胶共同增加(GS)和A2、B2共4种排放情景.分析表明在温室气体增加的情况下,这里未来的地面气温变化与全球和全国一样,都呈增加趋势.以GG和GS为例,GG情景下,这一地区的变暖幅度在21世纪末期达到4.2℃, GS情景下达到3.1℃.但总体来说这里的变暖幅度较全球和中国其它大部分地区小.各个季节中,冬春季的增温幅度大于夏秋季.对降水的分析表明,GG情景下长江中下游地区是中国降水增加较少的地区之一,而在GS情景下,降水将出现微弱的减少.区域气候模式的模拟,在气温变化方面得到的结果和全球模式类似.但降水与全球模式的结果有所差别,主要表现在降水增加的季节分布不同上,模拟结果中降水增加最多的是冬季和夏季(增加值分别为44%和23%),而春秋季的降水将减少. 相似文献
10.
采用树轮稳定碳同位素重建贺兰山1890年以来夏季(6~8月)气温 总被引:29,自引:0,他引:29
贺兰山油松稳定碳同位素分析结果表明, 当年6~8月的平均气温越高, 树轮a-纤维素中的d13C值则越高; 反之, 6~8月的平均气温越低, δ13C值越低. 在此基础上, 采用转换函数对贺兰山地区夏季6~8月气温进行了模拟重建, 重建序列的解释方差为34.9% (F = 15.01, p<0.001). 中国夏季(6~8月)的最高气温时段(20世纪20年代后期至30年代)在重建序列中被证实. 同时1910年以来贺兰山地区夏季气温与热带太平洋海温遥相对应, 尤其是1920年前后、1947年前后的极端低温时段与热带太平洋海温的冷气候态非常一致. 表明贺兰山地区气候信号不仅含有区域特征, 同时也受全球大尺度气候变化的影响. 功率谱分析表明, 贺兰山地区夏季(6~8月)气温存在2.56~2.63 a的准周期. 相似文献
11.
Daily temperature and precipitation data from 136 stations of Southwest China (SWC) during the last five decades, from 1960 to 2007, were analysed to determine the spatial and temporal trends by using the Mann–Kendall trend test. Results show that SWC has become warmer over the last five decades, especially in the recent 20–25 years. The increasing trends in winter months are more significant than those in the months of other seasons, and spatially Tibet, Hengduan mountains area and west Sichuan Plateau have larger temperature trend in magnitude than the other regions have. A downward trend was detected in Sichuan Basin also, but the region with cooler temperature was shrinking due to the statistically significant increasing trend of temperature after 1990s. Both annual and seasonal means of daily maximum and minimum temperatures show an increasing trend, but trend magnitude of minimum temperature was larger than that of maximum temperature, resulting in the decrease of diurnal temperature range for SWC in the last 50 years. Annual precipitation showed slightly and statistically insignificant increasing trend, but statistically significant increasing trend has been detected in winter season while autumn witnessed a statistically significant decreasing trend. The results could be a reference for the planning and management of water resources under climate change. Copyright © 2010 John Wiley & Sons, Ltd. 相似文献
12.
13.
Qiang Zhang Chong-Yu Xu Zengxin Zhang Yongqin David Chen 《Stochastic Environmental Research and Risk Assessment (SERRA)》2009,23(6):721-735
The spatial and temporal patterns of the temperature extremes defined by 5th and 95th percentiles based on daily maximum/minimum
temperature dataset were analyzed using Mann–Kendall test and linear regression method. The research results indicate that:
(1) the seasonal minimum temperature is in stronger increasing trend than the seasonal maximum temperature; (2) in comparison
with the changes of the maximum temperature, more stations display significantly increasing trends of minimum temperature
in frequency and intensity; (3) comparatively, more stations have significantly decreasing trends in the intra-seasonal extreme
temperature anomaly in summer and winter than in spring and autumn. The areal mean minimum temperature is in stronger increasing
trend than areal mean maximum temperature; (4) the warming process in the Far-West (FW) China is characterized mainly by significantly
increasing minimum temperature. The research will be helpful for local human mitigation to alterations in water resource and
ecological environment in FW China due to changes of temperature extremes, as the ecologically fragile region of China. 相似文献
14.
J. Abaurrea J. Asín A. C. Cebrián 《Stochastic Environmental Research and Risk Assessment (SERRA)》2015,29(1):309-322
A joint model is proposed for analyzing and predicting the occurrence of extreme heat events in two temperature series, these being daily maximum and minimum temperatures. Extreme heat events are defined using a threshold approach and the suggested model, a non-homogeneous common Poisson shock process, accounts for the mutual dependence between the extreme events in the two series. This model is used to study the time evolution of the occurrence of extreme events and its relationship with temperature predictors. A wide range of tools for validating the model is provided, including influence analysis. The main application of this model is to obtain medium-term local projections of the occurrence of extreme heat events in a climate change scenario. Future temperature trajectories from general circulation models, conveniently downscaled, are used as predictors of the model. These trajectories show a generalized increase in temperatures, which may lead to extrapolation errors when the model is used to obtain projections. Various solutions for dealing with this problem are suggested. The results of the fitted model for the temperature series in Barcelona in 1951–2005 and future projections of extreme heat events for the period 2031–2060 are discussed, using three global circulation model trajectories under the SRES A1B scenario. 相似文献
15.
Estimating the effects of climate change on the intensification of monsoonal‐driven stream discharge in a Himalayan watershed 
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下载免费PDF全文 Understanding potential hydrologic influences to continued climate change in Himalayan watersheds is important for management of transnational water resources. This study estimates the climate change impacts on hydrologic processes of the Kali Gandaki watershed from central Himalayan region using the Soil and Water Assessment Tool. Daily predicted stream discharge of the basin for 1981–95 following calibration was accurate with Nash Sutcliffe Efficiency value >0.75. Sensitivity analysis of the hydrologic parameters showed the precipitation and temperature lapse rates as the most sensitive parameters to the stream discharge. To assess the influence of continued climate change on hydrologic processes, we modified the weather inputs for the model using average, minimum and maximum temperature, and precipitation changes for the Special Report on Emission Scenarios B1, A1B and A2 derived from 16 General Circulation Models for 2080s. Mean annual stream discharge was approximately 39% higher than current values for the maximum temperature and precipitation changes of the A2 scenario and 22% less for minimum changes of the same scenario. Stream discharge was projected to be changed by +9% during monsoon season and by ?6% during pre‐monsoon season. Snowfall and snow melt were projected to be 30% and 29%, respectively, less than the current average for the maximum temperature and precipitation changes of the A2 scenario. Future simulations showed potential increase in monsoonal stream discharge associated with projected higher precipitation which when coupled with enhanced summer glacier melt might influence the downstream water availability of the basin. Copyright © 2013 John Wiley & Sons, Ltd. 相似文献
16.
With increasing uncertainties associated with climate change, precipitation characteristics pattern are receiving much attention these days. This paper investigated the impact of climate change on precipitation in the Kansabati basin, India. Trend and persistence of projected precipitation based on annual, wet and dry periods were studied using global climate model (GCM) and scenario uncertainty. A downscaling method based on Bayesian neural network was applied to project precipitation generated from six GCMs using two scenarios (A2 and B2). The precipitation values for any of three time periods (dry, wet and annual) do not show significant increasing or decreasing trends during 2001–2050 time period. There is likely an increasing trend in precipitation for annual and wet periods during 2051–2100 based on A2 scenario and a decreasing trend in dry period precipitation based on B2 scenario. Persistence during dry period precipitation among stations varies drastically based on historical data with the highest persistence towards north‐west part of the basin. Copyright © 2009 John Wiley & Sons, Ltd. 相似文献