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基于东北地区89个气象站点观测数据及IPCC AR4中ECHAM5/MPI-OM模式降尺度的0.5°×0.5°分辨率的月平均降水格点场资料,结合统计学相关系数以及干旱评价指数Z指数,评估了气候模式对该地区降水变化的模拟能力,并对其未来50年东北地区旱涝时空演变规律进行了预估。结果表明:(1)东北区及其各省实测年降水与模拟值时空上拟合度较差,修正后的数据模拟能力有较大提高;(2)未来50年全区及东三省降水呈上升趋势,内蒙古东部地区则呈减少趋势,且具有2015~2034年降水持续减少,2035后干湿交替发生特征;(3)未来东北地区旱涝依然呈广发、频发态势,且洪涝更为突出,旱涝多发区主要集中在三江平原、松嫩平原以及辽河平原等地。
Abstract:Based on the observed data from 89 meteorological stations in the Northeast China and the average monthly gridded precipitation data with the resolution of 0. 5° × 0. 5°downscaled from the mode of ECHAM5 / MPI- OM in IPCC AR4,the ability of the climate model to simulate the precipitation change within the region is pre-estimated in combination with the relevant statistical coefficients and the Z index for drought assessment,and then the evolution law of drought and water logging therein over the next 50 years is pre-estimated as well. The result shows that( 1) the spatial-temporal fitting between the observed annual precipitation and its simulated value of the Northeast China and all the provinces in the region is poorer,nevertheless,the data simulation ability is largely enhanced after the correction concerned;( 2) the precipitation in the Northeast China and all the provinces in the region has a trend of rising,however,a reducing trend is there in the east area of the Inner Mongolia with the feature of continuous reduction of precipitation from 2015 to 2034 and the alternated occurences of both drought and water logging after 2035;( 3)in the future,the region still has a tendency of wide and frequent occurrence of drought and water logging,especially,flood and water logging are to be quite serious,while flood and water logging are mostly concentrated within the areas of Sanjiang Plains,Songnen Plains,Liaohe River Plain,etc.
[1]Working Group 2 of IPCC.Climate change 1995:Impacts,adaptations and mitigation of climate change:Scientific-technical analyses[M].UK:Cambridge University Press,1996.20-1001.
[2]Working Groupof IPCC.Climate change 2001:Impacts,adaptation and vulnerability[J/OL].http://www.1grida1no/climate/ipcc-tar/wg2/index1htm,2006.
[3]韩冬梅,杨贵羽,严登华,等.近50年东北地区旱涝时空特征分析[J].水电能源科学,2014(6):5-8.
[4]刘吉峰,李世杰,丁裕国.基于气候模式统计降尺度技术的未来青海湖水位变化预估[J].水科学进展,2008,19(2):184-191.
[5]Wigley T M L,Jones P D,Brifa K R,et al.Obtaining sub-grid-scale information from coarse resolution general circulation model output[J].Journal Geophysics Research,1990,95(D2):1943-1953.
[6]陈华,郭家力,郭生练.统计降尺度方法及其评价指标比较研究[J].水利学报,2012,43(8):891-897.
[7]Wood A W,Leung L 5R,Sridhar V,et al.Hydrologic implications of dynamical and statistical approaches to downscaling climate model outputs[J].Climatic Change,2004,62:189-216.
[8]Grotch S L,Mac Cracken M C.The use of general circulation models to predict regional climatic change[J].J Climate,1991(4):286-303.
[9]Adam J C,Lettenmaier D P.Adjustment of global gridded precipitation for systematic bias[J].Journal of Geophysical Research,2003,108:1-14.
[10]高霁,杨红龙,陶生才,等.未来情景下东北地区极端气候事件的模拟分析[J].中国农学通报,2012,28(14):295-300.
[11]Maurer E P,Adam J C,Wood A W.Climate model based consensus on the hydrologic impacts of climate change to the Rio Lempa basin of Central America[J].Hydrology and Earth System Sciences,2009,13:183-194.
[12]袁文平,周广胜.标准化降水指数与Z指数在我国应用的对比分析[J].植物生态学报,2004,28(4):523-529.
[13]鞠笑生,邹旭恺.气候旱涝指标方法及其分析[J].自然灾害学报,1998,7(3):51-57.
[14]Shahabfar A,Eitzinger J.Spatio-temporal analysis of droughts in semi-arid regions by using meteorological drought indices[J].Atmosphere,2013,4(2):94-112.
[15]Yuan X C,Zhou Y L,Jin J L,et al.Risk analysis for drought hazard in China:a case study in Huaibei Plain[J].Natural hazards,2013,67(2):879-900.
[16]Li B,Liang Z,Yu Z,et al.Evaluation of drought and wetness episodes in a cold region(Northeast China)since 1898 with different drought indices[J].Natural Hazards,2014,71(3):2063-2085.
[17]郭志辉,杨贵羽,王喜风.松辽流域近50年来降水演变规律分析[J].人民黄河,2012,33(12):35-37.
[18]王越,江志红,张强,等.基于Palmer湿润指数的旱涝指标研究[J].南京气象学院学报,2007,30(3):383-389.
[19]马建勇,许吟隆,潘婕.基于SPI与相对湿润度指数的1961~2009年东北地区5~9月干旱趋势分析[J].气象与环境学报,2012,28(3):90-95.
[20]严登华,袁喆,杨志勇,等.1961年以来海河流域干旱时空变化特征分析[J].水科学进展,2013,24(1):2-7.
[21]刘志雄,肖莺.长江上游旱涝指标及其变化特征分析[J].长江流域资源与环境,2012,3:426-430.
[22]Wu H,Hayes M J,Weiss A,et al.An evaluation of the standardized precipitation index,the China-Z index and the statistical ZScore[J].International journal of climatology,2001,21(6):745-758.
[23]孟莹,卢娟,陈传雷.辽宁3种旱涝指标的对比分析[J].辽宁气象,2004(2):22-23.
[24]林盛吉,许月萍,田烨,等.基于Z指数和SPI指数的钱塘江流域干旱时空分析[J].水力发电学报,2012(2):20-26.
[25]邵晓梅,劲松河北省旱涝指标的确定及其时空分布特征研究[J].自然灾害学报,2001,10(4):133-136.
[26]袁文平,周广胜.干旱指标的理论分析与研究展望[J].地球科学进展,2004,19(6):982-991.
[27]Qian W H,Zhu Y F.Climate change in china from 1880 to 1998and its impacts on the environmental condition[J].Climate Change,2001,50:419-444.
[28]王遵娅,丁一汇,何金海,等.近50 a来中国气候变化特征的再分析[J].气象学报,2004,62(2):228-236.
[29]唐亚平,张凯,李忠娴,等.1964~2008年辽宁省旱涝时空分布特征及演变规律[J].气象与环境学报,2011,27(2):50-55.
基本信息:
DOI:10.13928/j.cnki.wrahe.2015.10.001
中图分类号:P426.616
引用信息:
[1]韩冬梅,许新宜,杨贵羽,等.未来50年东北地区旱涝演变规律预估[J].水利水电技术,2015,46(10):1-6+21.DOI:10.13928/j.cnki.wrahe.2015.10.001.
基金信息:
国家重点基础研究发展计划(“973”计划)(2010CB 951100);; 我国旱涝事件集合应对战略研究(2012-ZD-13);; 国家科技支撑计划课题(2013BAB05B04)
2015-10-20
2015-10-20