且末红枣冬季冻害成因分析及防御措施研究

根据且末气象站1971—2012年冬季逐日气象资料和近年来枣树冻害灾情调查资料,分析了枣树冻害成因及冬季气象条件变化对枣树安全越冬的影响,开展防御措施对比观测,探讨科学的越冬防护措施。结果表明:枣树冻害发生与持续低温、积雪日数、树龄、树种、管理措施密切相关;冬季气候变暖对枣树安全越冬有利,但休眠前气温偏高易导致枣树冬前抗寒能力锻炼不足,对安全越冬不利;防护措施观测显示,根颈培土增温效果明显,降雪时包扎增温效果不佳;枣树越冬保护应因地制宜采用树干涂白、秋翻冬灌、培土、包扎等综合防护措施。     

使用加密降雪资料分析降雪量和积雪深度关系

降雪量和积雪深度的关系是降雪预报及相关科研工作中的重要参数,加密降雪资料的出现为分析这种关系提供了新的支持。利用2009—2011年冬季加密降雪资料并采用线性拟合方法,分析得出我国冬季积雪深度变化值和相应降雪量的比值大体为0.75 cm·mm-1,该比值随气温上升呈明显减小趋势,且有明显的地区差异,但未体现出显著的时间变化特征。降雪量和积雪深度的关系仍需深入分析,并需要更高质量降雪资料的支持,以便能应用到实际业务和科研工作中。     

Influence of climatic factors on the low yields of spring barley and winter wheat in Southern Moravia (Czech Republic) during the 1961–2007 period

The paper aims to study the variability of spring barley and winter wheat yields, the most important crops in the Czech Republic, with respect to the variability of weather and climatic factors. Yields of both crops have been studied for 13 districts in Southern Moravia for the 1961–2007 period. From detrended series of spring barley and winter wheat yields, years with very low (lower than the mean minus a 2.5-multiple of the standard deviation) and extremely low (interval given by the mean minus a 1.5- and 2.5-multiple of the standard deviation) yields were selected. Years in which at least one of the districts had extremely low/very low yields were further analyzed. From 10 such years selected separately for spring barley and winter wheat, six of them agreed for both crops. Extreme years were studied using NUTS4-level yield data with respect to temperature, precipitation, the self-calibrated Palmer Drought Severity Index (scPDSI), snow cover, frost patterns, and the onset and duration of select phenophases. Extremely/very low barley yields in 1993, 2000, and 2007 were related to high April–June (AMJ) temperatures, low AMJ precipitation totals, and negative AMJ scPDSI (indicating drought) with an earlier onset of flowering and full ripeness and shorter intervals from tillering to flowering and from flowering to full ripeness compared to the entire 1961–2007 mean. As for extremely/very low winter wheat yields, in addition to the previously mentioned factors, winter patterns also played an important role, particularly the occurrence of severe frosts with a coinciding lack of snow cover and a long-lasting snow cover (in highlands), indicating that low yields are the result of not only one unfavorable factor but a combination of several of them.     

黄淮海平原冬小麦最大可能蒸散的估算

作物最大可能蒸散考虑了作物及当地地表状况,为当地地表实际覆盖情况下实际蒸散的理论上限值,能客观分析作物对水分的需求程度和农业干旱状况。基于遥感（叶面积指数和地表反照率）数据和逐日气象数据,利用Penman-Monteith公式,计算黄淮海平原小麦种植区27个气象站冬小麦生育期2000-2015年逐日蒸散,提取得到冬小麦生育期逐日最大可能蒸散数据集,并分析其时空变化特征及成因。结果表明:与联合国粮农组织（FAO）单作物系数法计算的最大可能蒸散E_k对比,区域平均最大可能蒸散E_c的时间变化趋势与E_k一致,空间分布上E_c符合客观实际。黄淮海平原冬小麦全生育期、越冬期和返青-拔节期E_c均呈北低南高的分布特征,日平均值分别为1.99 mm,0.44 mm和2.75 mm;其余3个生育期（越冬前、抽穗期、乳熟-成熟期）在空间分布上差异不大,日平均值分别为1.23 mm,4.71 mm和3.74 mm。冬小麦不同生育期（含全生育期）E_c的空间分布主要受叶面积指数分布特征的影响,二者呈显著正相关关系。     

华北地区冬小麦产量预报模式的初步研究

本文提出了一种省级以上尺度的作物-天气产量预报模式。首先,对气候产量进行R-型聚类分析,将全区分成若干亚区;然后,用累加型及阶乘型的多重非线性回归方法组建预报方程。本文提出的模式,原则上可以适用于多种尺度和不同作物,预报时效也可以根据生产需要和作物发育阶段的特点给定。 华北地区冬小麦产量预报的时效,分为冬前、越冬后及黄熟前三个阶段。预报方程的复相关系数,分别可达到0.70,0.90和0.95以上;平均相对剩余误差为15％,8％和4％。     

河南省稻麦类作物对气候变化的响应

小麦和水稻是世界最重要的粮食作物。利用河南省小麦和水稻的历史观测资料,结合DSSAT-CERES小麦和ORYZA2000水稻模拟模型,分析和模拟河南省稻麦类作物在历史气候变化条件下生育期和产量的变化。结果表明:冬小麦全生育期长度呈缩短趋势,但播种-越冬天数平均每10 a增加1.7 d,开花到乳熟天数平均每10 a增加2-4 d,返青后各生育期均表现出不同程度的提前;水稻各生育期均有不同程度的提前,尤其是拔节期以前,分蘖前的生育期间隔天数以缩短为主,拔节后以延长为主。雨养小麦模拟产量和水氮增产潜力均呈减少趋势;随着播种期的提前,水稻减产趋势逐渐减弱。     

中国北方地区冬季雨雪年度变化与大气气溶胶分布特征研究

近年来,随着大气观测技术的快速发展,为冬季大雪年际变化研究提供了一些新的观测事实,增加了新的认识。认为大气环流对降雪的年际变化的影响只是重要方面之一。新的观测事实启示研究者,冬雪的年际变化和差异还可能与其他影响气候变化有更为复杂的因素——大气气溶胶特征有关。基于1980-2008年中国气象台站降水量资料和1980-2005年北方地区大气气溶胶光学厚度（AOD）资料,研究中国北方地区大范围多雨雪以及少雨雪年度变化与大气气溶胶分布特征的关系。结果表明：1980-2008年,中国北方地区典型的多雨雪年为1980、1984、1989、1993、1998、2003年和2006年;少雨雪年为1982-1983、1985-1988、1997、2001年和2005年。根据1980-2005年华北逐年冬半年雨雪总量与北方地区同期AOD相关分析,揭示中国北方地区雨雪年度变化与气溶胶光学厚度（AOD_550m）的年度变化存在正相关,相关系数达到0．001的显著性水平。同期资料AOD。。。分析表明,中国北方地区冬季多雨雪与少雨年大气气溶胶光学厚度差异显著,多雨雪年大气气溶胶光学厚度显著偏厚,中国华北北部、东北南部地区AOD正距平的平均值达到1×10。-5×10^-3,冬季北方地区少雨雪年与此差异显著,AOD为显著负距平,其平均值为-5×10^-3。     

青藏高原冬春季积雪异常对中国春夏季降水的影响

利用1956年12月～1998年12月共42a，青藏高原及其附近地区78个积雪观测站的雪深和我国160站月降水的距平资料，分析了其气候特征，并用SVD方法分析了冬春季积雪异常与春夏季我国降水异常的关系。用区域气候模式RegCM2模拟了青藏高原积雪异常的气候效应并检验了诊断分析的结果。分析表明，雪深异常，尤其是冬季雪深异常是影响中国降水的一个因子。研究证明，高原冬季雪深异常对后期中国区域降水的影响比春季雪深异常的影响更为重要。数值模拟的结果表明，高原雪深和雪盖的正异常推迟了东亚夏季风的爆发日期，减弱了季风强度，造成华南和华北降水减少，而长江和淮河流域降水增加。冬季雪深异常比冬季雪盖异常和春季雪深异常对降水的影响更为显著。机理分析指出，高原及其邻近地区的积雪异常首先通过融雪改变土壤湿度和地表温度，从而改变了地面到大气的热量、水汽和辐射通量。由此所引起的大气环流变化又反过来影响下垫面的特征和通量输送。在湿土壤和大气之间，这样一种长时间的相互作用是造成后期气候变化的关键过程。与干土壤和大气的相互作用过程有本质差别。     

河南省稻麦类作物对气候变化的响应

小麦和水稻是世界最重要的粮食作物。利用河南省小麦和水稻的历史观测资料,结合DSSAT-CERES 小麦和ORYZA2000水稻模拟模型,分析和模拟河南省稻麦类作物在历史气候变化条件下发育期和产量的变化。结果表明：冬小麦全育期长度呈缩短趋势,但播种-越冬天数平均每10年增加1.7天,开花到乳熟天数平均每10年增加2-4天,返青后各发育期均表现出不同程度的提前;水稻各发育期均有不同程度的提前,尤其是拔节期以前,分蘖前的发育期间隔天数以缩短为主,拔节后以延长为主。雨养小麦模拟产量和水氮增产潜力均呈减少趋势;随着播种期的提前,水稻减产趋势逐渐减弱。     

Relationship between winter snow cover days in Northeast China and rainfall near the Yangtze River basin in the following summer

Based on observed snow and precipitation data and NCEP/NCAR reanalysis data,the relationship between the number of winter snow cover days in Northeast China and the following summer’s rainfall in the northern part of southern China is analyzed and the possible underlying mechanisms are discussed.The results indicate that a negative relationship is significant throughout the study period,especially more obvious after the 1980s.The pre-winter circulation patterns in years with more snow cover days and less summer rainfall in the south bank of the Yangtze River are almost the same.In years with more snow cover days,lower temperatures at the lower level over Northeast China are found in winter and spring.The winter monsoon is weaker and retreats later in these years than in those with fewer snow cover days.In spring of years with more snow cover days,anomalous cyclonic circulation is observed over Northeast China,and anomalous northerly wind is found in eastern China.In summer of these years,anomalous northeasterly wind at the lower level is found from the area south of the Yangtze River to the East China Sea and Yellow Sea;and with less southwesterly water vapor transport,the rainfall in the area south of the Yangtze River is less than normal,and the opposite patterns are true in years with fewer snow cover days.In recent years,the stable relationship between winter snow cover in Northeast China and summer rainfall in the Yangtze River basin can be used for summer rainfall prediction.The results are of great importance to short-term climate prediction for summer rainfall.     

Western Himalayan snow cover and Indian monsoon rainfall: A re-examination with INSAT and NCEP/NCAR data

Summary ?This study presents the monthly climatology and variability of the INSAT (Indian National Satellite) derived snow cover estimates over the western Himalayan region. The winter/spring snow estimates over the region are related to the subsequent summer monsoon rainfall over India. The NCEP/NCAR data are used to understand the physical mechanism of the snow-monsoon links. 15 years (1986–2000) of recent data are utilized to investigate these features in the present global warming environment. Results reveal that the spring snow cover area has been declining and snow has been melting faster from winter to spring after 1993. Connections between snow cover estimates and Indian monsoon rainfall (IMR) show that spring snow cover area is negatively related with maximum during May, while snow melt during the February–May period is positively related with subsequent IMR, implying that smaller snow cover area during May and faster snow melt from winter to spring is conducive for good monsoon activity over India. NCEP/NCAR data further shows that the heat low over northwest India and the monsoon circulation over the Indian subcontinent, in particular the cross-equatorial flow, during May are intensified (weakened) when the snow cover area during May is smaller (extensive) and snow melts faster (slower) during the February–May period. The well-documented negative relationship between winter snow and summer rainfall seems to have altered recently and changed to a positive relationship. The changes observed in snow cover extent and snow depth due to global warming may be a possible cause for the weakening winter snow–IMR relationship. Received January 15, 2002; revised May 5, 2002; accepted June 23, 2002     

融雪性降水量资料实时处理技术

介绍区域自动站冬季融雪产生的雨量记录的识别和自动处理的方法。将融雪性降水量的识别分为降雪和融雪两个过程。在满足降雪的前提条件下,测站有雨量记录,且当时符合融雪条件,则该雨量记录作为融雪产生的记录处理。据实际使用自动识别的准确率可达90%以上。降雪和融雪的条件以区域自动站的气温作为主要依据,结合临近的国家气象观测站资料进行综合判别。为提高对天气状况和降水性质的识别还加入了雷达估测降水和冬季降水相态判别等产品,弥补用单一参考站降水资料的缺陷,对融雪雨量记录识别效果有显著作用。     

冬季积雪的异常分布型及其与冬、夏大气环流的耦合关系

采用 ECMWF1 979～ 1 993年 2 .5°× 2 .5°的网格点积雪深度资料 ,研究了较为细致的积雪异常的空间分布特征 ,揭示了欧亚大陆冬季积雪的异常空间分布型 ;并采用 SVD方法研究了冬季积雪的异常分布型与冬、夏大气环流的耦合关系。结果表明 :欧亚大陆冬季积雪深度存在典型的异常空间分布型 ;积雪的异常分布型与冬、夏大气环流之间均存在一定的耦合关系。冬季积雪的异常分布型与大气 EU遥相关型存在明显的同时性相互作用 ,大气 EU遥相关型有利于冬季积雪异常分布型的出现和维持 ,而积雪异常分布型对大气 EU遥相关型的发生起一定的作用 ,进而对冬季风活动产生影响。冬季积雪的这种异常分布型与夏季大气环流 ,尤其是东亚地区的夏季大气环流 ,也存在一定的联系。积雪异常分布型可以通过影响副热带高压的南北进退 ,对东亚季风及中国夏季雨带产生影响。     

青藏高原东部牧区雪灾的气候特征分析

通过对 196 7— 1996年 2 5个测站的雪灾资料分析 ,揭示了青藏高原东部牧区有雪灾期从上年10月到当年 5月长达 8个月 ,雪灾在一年之中有 3个高发月 :11月、3月和 2月 ;雪灾主要发生在巴颜喀拉山南缘和东麓地区 ,近 30a来呈上升趋势。 196 8— 1976年冬春为一较长时段的雪灾发生的低值期 ,从 1977— 1992年有 3个高峰期和 2个低谷期 ,从 1993年开始又进入高发期 ;高原东部牧区冬春雪灾存在着明显的 5 6a的和较弱的 2 3a周期变化。本文中定义发生在 15月的雪灾为后冬雪灾 ,发生在10 12月的雪灾为前冬雪灾。研究表明 ,70年代是前冬雪灾的高发期 ,80年代末到 90年代是后冬雪灾的高发期。雪灾期西太副高的年际差异是雪灾发生年际振荡的一个可能原因     

青藏高原积雪异常对高原地面加热的影响

On the basis of snow data and AWS (Automatic Weather Station) data obtained from the Tibetan Plateau in recent years (1993 to 1999), the features of sensible heat, latent heat and net long-wave radiations are estimated, and their variations in more-snow year (1997/1998) and less-snow year (1996/1997) are analyzed comparatively. The relationships between snow cover of the Tibetan Plateau and plateau＇s surface heating to the atmospheric heating are also discussed. The difference between more-snow and less-snow year in spring is remarkably larger than that in winter. Therefore, the effect of anomalous snow cover of the Tibetan Plateau in winter on the plateau heating appears more clearly in the following spring of anomalous snow cover.     

冬季高原积雪和欧亚积雪对我国夏季旱涝不同影响关系的环流特征分析

冬季高原积雪和欧亚积雪异常对我国夏季旱涝有一定的影响作用,但是它们与我国夏季降水的相关分布基本上是相反的.通过冬季积雪与北半球500hPa高度场的相关分析,从春季和夏季平均环流场对前期冬季高原积雪和欧亚积雪异常的不同响应,来探讨冬季高原积雪和欧亚积雪与我国夏季降水不同相关关系的原因,也为积雪因子在我国汛期旱涝预测中的应用提供一定的物理基础.     

青藏高原冬春雪深分布与中国夏季降水的关系

利用SSMR和SSM／I卫星遥感雪深反演资料,通过与高原测站雪深观测资料的对比分析,揭示了高原雪深的时空分布特征,在此基础上对积雪异常年中国夏季降水异常和大气环流进行了对比分析。结果表明,卫星遥感雪深资料可较真实反映出高原积雪的状况,并可反映出高原西部积雪的变化;高原冬、春季积雪EOF分解第1模态具有相同的空间分布,反映了高原冬、春季积雪分布具有相当的一致性,而春季积雪的第2模态则反映高原积雪的东西差异;冬、春季雪深EOF第1模态的时间序列与中国夏季降水的相关分析表明,大致以长江为界,我国东部地区呈现出南涝北旱的分布模态,春季高原东（西）部多（少）雪与东（西）部少（多）雪年的夏季,我国东部降水表现出长江以南（北）地区为大范围的降水偏多（少）。     

青藏高原冬季积雪与河南汛期降水关系

利用1961－1998年河南郑州，安阳等50站降水资料和青藏高原冬季积雪日数资料，分析了青藏高原冬季积雪与河南汛期降水的关系，结果表明，青藏高原冬季积雪与河南南部汛期降水较好的关系，而与河南北部汛期降水呈反相关，多雪年汛期河南南部降水偏多的概率占61％，北部降水偏少的概率占56％，少雪年汛期河南部降水偏少的概率为72％，河南北部降水偏多的概率为61％。     

Response of the Indian summer monsoon circulation and rainfall to seasonal snow depth anomaly over Eurasia

Several observational and modeling studies indicate that the Indian summer monsoon rainfall (ISMR) is inversely related to the Eurasian snow extent and depth. The other two important surface boundary conditions which influence the ISMR are the Pacific sea surface temperature (SST) to a large extent and the Indian Ocean SST to some extent. In the present study, observed Soviet snow depth data and Indian rainfall data for the period 1951–1994 have been statistically analyzed and results show that 57% of heavy snow events and 24% of light snow events over west Eurasia are followed by deficient and excess ISMR respectively. Out of all the extreme monsoon years, care has been taken to identify those when Eurasian snow was the most dominant surface forcing to influence ISMR. During the years of high(low) Eurasian snow amounts in spring/winter followed by deficient(excess) ISMR, atmospheric fields such as temperature, wind, geopotential height, velocity potential and stream function based on NCEP/NCAR reanalyses have been examined in detail to study the influence of Eurasian snow on the midlatitude circulation regime and hence on the monsoon circulation. Results show that because of the west Eurasian snow anomalies, the midlatitude circulations in winter through spring show significant changes in the upper and lower level wind, geopotential height, velocity potential and stream function fields. Such changes in the large-scale circulation pattern may be interpreted as precursors to weak/strong monsoon circulation and deficient/excess ISMR. The upper level velocity potential difference fields between the high and low snow years indicate that with the advent of spring, the winter anomalous convergence over the Indian region gradually becomes weaker and gives way to anomalous divergence that persists through the summer monsoon season. Also the upper level anomalous divergence centre shifts from over the Northern Hemisphere and equator to the Southern Hemisphere over the Indian Ocean and Australia.     

基于MTM-SVD方法的黄河流域夏季降水年际变化及其主要影响因子分析

应用中国气象台站积雪日数资料和NCEP/NCAR再分析资料以及多锥度—奇异值分解方法 (MTM-SVD),分析了近50年来黄河流域夏季降水的时空变化及其影响因子.发现黄河流域夏季降水存在显著的2～3年周期.在准3年周期上黄河流域夏季降水对前冬青藏高原东部积雪日数有很好的响应,当前冬高原积雪日数以正 (负) 异常为主时,接下来的夏季黄河流域降水偏少 (多).这种响应存在年代际变化,在1983年之前最为明显,1983~1993年是个调整时期,1993年以后又开始明显.在准2年周期上黄河流域夏季降水对前冬西太平洋暖池SST有很好的响应,当前冬西太平洋暖池SST偏高 (低) 时,接下来的夏季黄河流域降水表现为东多 (少)西少 (多) 型.这一响应同样存在年代际变化.前冬高原积雪和西太平洋暖池SST是影响黄河流域夏季降水的重要因子.