中国木本植物物候变化特征分析

利用1963—1988年中国木本植物物候观测资料,运用趋势分析的方法研究了26 a来全国21个站的木本植物物候变化特征。结果表明:26 a来,全国各地区木本植物春季物候期和秋季物候期大体上都是推迟的,1976—1988年与1963—1975年相比,绝大多数植物物候期都有明显推迟,部分植物物候期推迟了10 d以上。     

1986-2010年巴楚木本植物物候变化特征及其对气候变化的响应分析

利用巴楚国家基本气候站1986-2010年的气象观测数据和地面物候观测资料,采用气候倾向率和气候趋势系数方法,分析气温、降水、日照时数的变化特征;木本植物选用新疆杨(Populus bolleanalanche),垂柳(Salix babylonica),杏树(Prunus armeniaca),苹果树(Malus pumila),沙枣树(Fdeagnys Qxycarpasehlecht),对植物物候期与气候变化的相互关系进行研究。研究表明：近25年来巴楚气候增暖现象较明显,增温率为0.18～0.95℃/10a,春、秋季变暖的趋势大于冬、夏季;降水量变化趋势不明显,整体呈现减少趋势,气候倾向率为-0.61 mm/10a,春、夏降水量呈减少趋势,冬、秋两季降水量均呈增多趋势;年日照时数呈减少趋势,气候倾向率为-30.34h/10a。除春季日照时数表现为增加趋势外,其他季节均表现为不同程度的减少趋势。其中,以冬季减幅最显著,平均减少-27.09h/10a。近25a来喀什木本植物芽开放期、展叶始期、开花始期表现为一致的提前趋势, 叶变色始期和落叶始期表现推迟的趋势;影响植物物候期的主要气候因子为气温和日照时数,随气温升高、日照时数增多,植物生长季延长。木本植物春季物候期与春季气温和春季日照时数呈负相关,且相关性显著,而与冬季气温和冬季日照时数几乎没有显著相关性。木本植物物候与秋季温度呈正相关,秋季气温升高,物候期推迟。在生产生活中,根据植物的物候期变化安排农、林业生产有重要的意义。     

气温对巴楚县乔木物候的影响

利用新疆巴楚气象站1987—2013年物候资料和气象资料,运用线性回归、t检验、相关分析等方法,分析了巴楚县气温和乔木物候期的变化特征,以及气温对植物物候期的影响。结果表明：近27a巴楚县乔木春季展叶始期表现出明显提前趋势,秋季叶变色始期表现出推迟趋势,生长季明显延长;3月份气温对展叶始期的影响最显著,巴楚县3月份气温每上升1℃,乔木展叶始期提前2.6d。     

鲁西南木本植物生长季及物候期持续日数对气候变暖的响应

以1981-2010年中国鲁西南地区的植物为研究对象,采用统计分析法研究7种木本植物生长季与物候期持续日数对气候变暖的响应规律。结果表明：1981-2010年中国鲁西南地区气温呈极显著上升趋势（p<0.01）,随着气候变暖,木本植物春季物候期间隔缩短,秋季物候期间隔延长,全生长季延长,且全生长季变化趋势比各物候持续期变化趋势明显;展叶持续期主要与上月、当月和持续月平均气温呈负相关,其中梧桐展叶持续期与当月平均气温呈极显著负相关（p<0.01）;旱柳和刺槐开花持续期与持续月平均气温呈显著正相关（p<0.05）;叶变色持续期和落叶持续期与上月、当月、结束月和持续月平均气温呈正相关,其中旱柳与平均气温达到显著正相关（p<0.05）。木本植物全生长季与气温呈正相关,其中旱柳生长季变化对气候变暖的响应最敏感,其次是榆树、梧桐和楝树生长季变化对气候变暖的响应较敏感;随着年平均气温每升高1 ℃,植物生长季延长3.0-20.0 d;年平均最高气温每升高1℃,生长季延长5.0-14.0 d;年平均最低气温每升高1 ℃,生长季延长2.0-18.0 d。     

吉林省蒲公英物候特征及其对气候变暖的响应

利用数理统计方法,对在气候变暖背景下吉林省蒲公英物候期变化进行分析,探讨了蒲公英物候期变化与春季、秋季气温的关系。结果表明：自1980年以来,吉林省春、秋季增温显著,且秋季较春季明显;吉林省西部地区展叶期推迟,黄枯期提前,生长季缩短;中部地区基本无变化;东部地区展叶期提前,黄枯期推迟,生长季延长。温度和物候期的变化趋势均有明显的地域特征,展叶期变化趋势在地域分布上恰好与春季气温一致,在湿润的东部地区,黄枯变化趋势与秋季气温一致,在干旱的西部地区,枯黄期变化趋势与秋季气温变化相反。探讨了对东西部物候期变化截然相反趋势的原因,并通过线性回归分别建立了各站物候期的温度模型。     

桂林市气候变暖特征及其对柑桔物候期的影响

利用桂林市1984-2014年气候资料和同期柑桔物候资料,运用线性倾向估计、SPSS相关系数等方法研究了桂林市气候变暖的特征及其对柑桔物候期的影响。结果表明:31年中桂林市气候变暖趋势明显,其主要特点是年平均气温上升幅度约为0.4℃,20世纪90年代后期和21世纪初升温显著,在升温过程中以春季升温为主,冬季次之,夏季、秋季略升温,气候变暖春季气温升高贡献最大。气候变暖引起柑桔物候期的变化明显,春季物候期提前,秋季物候期推迟,生长季呈延长的趋势;气温是影响柑桔物候期最为显著的气象因子;2月平均最高气温升高1℃,柑桔芽开放期提前约3.4天,3月平均最高气温升高1℃,开花期提前约4.9天,年极端最高气温升高1℃,可采成熟期推迟6.8天。     

影响鲁西南木本植物秋季物候期的气象要素分析

选取鲁西南地区1981—2020年旱柳、榆树、合欢、楝树4种不同科属典型木本植物物候期资料,结合当地相应时期的气候资料进行相关性分析,研究气象要素变化对不同种类木本植物秋季物候期产生的影响。结果表明：（1）鲁西南地区1981—2020年平均日平均气温、平均日最低气温均呈极显著上升趋势,上升速率分别为0482 ℃/10 a、0609 ℃/10 a。（2）受气候变化影响,鲁西南地区四种木本植物的秋季物候期均呈推迟趋势,榆树、旱柳对于气候变化的敏感度高于其他两种木本植物,木本植物的秋季物候期中落叶末期对气候变化响应最为强烈。（3）鲁西南地区木本植物秋季物候期变化受气温、地温、风速的影响较大,其中气温、地温越高,木本植物秋季物候期会出现的越晚;风速越大,木本植物秋季物候期会出现的越早。（4）鲁西南地区木本植物秋季物候期虽受日照、降水、空气湿度等气象要素影响,但影响并不显著。     

气温对吐鲁番地区木本植物春季物候的影响

利用吐鲁番和鄯善1980-2004年气象资料以及同期春季物候资料,统计分析了吐鲁番地区气温和木本植物春季物候的变化趋势及其相关性;各物候间的相关关系以及不同时段气温变化对物候的影响。在此基础上探讨了未来气候变化对吐鲁番地区木本植物春季物候的可能影响。     

中国植物物候变化预测

根据中国20个观测站点的木本、草本植物物候资料,结合气温、降水资料,预测了1989～2099年植物始展叶期、始花期物候,结果表明：未来我国气温、降水、季节开始时间变化,对我国植物物候期有明显的影响,其中气温对物候期的作用最为显著。春季气温升高,春季物候期提前,未来全国5区植物始展叶期、始花期均以显著的提前趋势为主,植物...     

气候变化对阴山北麓木本植物物候期的影响

本文基于内蒙古农牧业气象观测站1994—2015年旱柳、榆树和小叶杨三种木本植物物候观测资料及同期气候数据,采用线性倾向估计、Pearson相关系数等方法,探讨了气候变化对阴山北麓木本植物物候的影响。结果表明：近22 a,阴山北麓旱柳、榆树和小叶杨的花芽开放期和落叶末期均表现为提前趋势,且落叶末期提前幅度较大,平均每10 a分别提前2.9 d、3.6 d、4.6 d。生长季缩短,平均生长季长度为182 d。气温是影响旱柳、榆树、小叶杨春季花芽开放期的关键气象因子,春季气温每升高1℃,花芽开放期提前4.1 d;而落叶末期对降水量较为敏感,水分条件是阴山北麓木本植物落叶末期的主要限制因子。     

中国植物物候变化特征及其对降水变化的响应

利用1963~1988年中国木本草本植物物候观测资料,运用趋势分析和相关分析方法,研究了26年中国20个物候站点植物始展叶期、始花期、始落叶(黄枯)期物候变化特征及其对降水变化的响应。结果表明:1963~1988年我国植物始展叶期、始花期、始落叶(黄枯)期均以推迟趋势为主;春季始展叶期、始花期,东北、华北以提前趋势为主,其他各区以推迟趋势为主;秋季始落叶(黄枯)期华北以提前趋势为主,其他各区以推迟趋势为主;1980年前后的物候期变化与1963~1988年的变化相同;春季物候期平均值差异多在-3~6天,秋季物候期平均值差异多在-10~10天;我国植物的始展叶期、始花期、始落叶(黄枯)期对于之前月份的累积降水量有不同程度的响应,物候期对该物候期前1月至前3月的累积降水量响应最为明显;我国春季物候期与降水量以正相关为主,秋季物候期与降水量则以负相关为主。      

Spring Phenophases in Recent Decades Over Eastern China and Its Possible Link to Climate Changes

In light of the observed climate changes in recent decades over eastern China, we studied the changes in spring phenophases of woody plants observed at 16-stations during 1963–1996, and explored the possible link between the spring phenophases changes and climate changes before the phenophase onset. It is found that, in the region north of 33^∘N (including Northeast, North China and the lower reaches of the Huaihe River), the phenophase advanced 1.1–4.3 days per decade for early spring and 1.4–5.4 days per decade for late spring, but in the eastern part of the southwest China it was dealyed by 2.9–6.9 days per decade in early spring and 2.4–6.2 days per decade in late spring. One outstanding feature is identified in Guangzhou in south China, where significant advance of 7.5 days per decade in early spring and delay of 4.6 days per decade in late spring were detected. Statistically siginficant correlation was found between the changes of spring phenophase and the temperatures of one or several months before the phenophase onset. The relationship between the trend of phenophase change and temperature change was highly non-linear (more sensitivity to cooling than to warming) and reached an asymptote 0.5^∘C per decade, which may have implication in the responses of the ecosystem in a future global warming scenario. In addition, we also examined the link between the spring phenophase, and length and mean temperature of the growing season, and the analyses suggested that they were highly correlated as well.     

基于遥感数据的内蒙古草原灌丛物候变化研究

植被物候研究是全球气候变化研究的重要内容,但国际上有关干旱半干旱区灌丛物候变化的研究还很缺乏。为了探讨气候变化对内蒙古草原灌丛物候的影响,利用2000~2011年的MODIS EVI时间序列影像,采用动态阈值法得到6种灌丛12 a物候年际变化情况,结合样点附近气象站的气温和降水数据,分析了灌丛物候与气候变化的动态关系。结果表明：（1）内蒙古中西部草原灌丛返青期、枯黄期都呈现提前的趋势,生长季长度缩短;（2）春季均温升高和前一年秋冬降水增加可以提前灌丛返青期,是影响返青期的主要因素;（3）秋季降水减少和夏秋均温上升都利于枯黄期提前,夏季降水的作用则因灌丛种类不同而略有差异;（4）夏秋均温上升缩短了生长季长度,夏秋降水量、春季均温则多与生长季长度呈正相关。     

Changes of Accumulated Temperature, Growing Season and Precipitation in the North China Plain from 1961 to 2009

Using the high-quality observed meteorological data, changes of the thermal conditions and precipitation over the North China Plain from 1961 to 2009 were examined. Trends of accumulated temperature and negative temperature, growing season duration, as well as seasonal and annual rainfalls at 48 stations were analyzed. The results show that the accumulated temperature increased significantly by 348.5℃ day due to global warming during 1961-2009 while the absolute accumulated negative temperature decreased apparently by 175.3℃ day. The start of growing season displayed a significant negative trend of -14.3 days during 1961- 2009, but the end of growing season delayed insignificantly by 6.7 days. As a result, the length of growing season increased by 21.0 days. The annual and autumn rainfalls decreased slightly while summer rainfall and summer rainy days decreased significantly. In contrast, spring rainfall increased slightly without significant trends. All the results indicate that the thermal conditions were improved to benefit the crop growth over the North China Plain during 1961-2009, and the decreasing annual and summer rainfalls had no direct negative impact on the crop growth. But the decreasing summer rainfall was likely to influence the water resources in North China, especially the underground water, reservoir water, as well as river runoff, which would have influenced the irrigation of agriculture.     

1971~2013年我国四季开始日期及生长期长度的变化特征分析

利用中国气象局国家气象信息中心提供的中国584个气象站点1971～2013年的逐日气温数据,采用线性倾向估计和经验模态分解（EMD）等方法,以地理信息系统为数据处理平台,分析我国43年来四季起始日以及生长期的变化特征。结果表明：新疆、云南和四川地区的四季起始日变化呈现明显的南北差异;全国大部分地区春、夏季起始日提前,春季比夏季提前趋势更明显,江苏、安徽、湖北大部和云南北部春季提前显著,提前率为4.1～7.2 d/10 a;夏季提前的区域更广,新疆东部、甘肃西部、华南大部和云南南部夏季提前显著,提前率为2.9～4.6 d/10 a;全国大部分地区秋、冬季起始日推迟,秋季比冬季推迟的范围更大,新疆南部和四川西部秋季推迟明显,推迟率为4.4～8.6 d/10 a;冬季推迟趋势更显著,新疆东南部和青海大部冬季推迟明显,推迟率为4.7～13.8 d/10 a;全国各地区生长期均有延长,最显著的是云川交界处和新疆东南部地区,延长率为20.1 d/10 a。EMD和线性倾向估计的结果基本一致,但EMD得到的春季起始日推迟地区的范围更大,夏、秋、冬季起始日以及生长期的变化趋势更显著。     

Changes of Accumulated Temperature, Growing Season andPrecipitation in the North China Plain from 1961 to 2009

Using the high-quality observed meteorological data,changes of the thermal conditions and precipitation over the North China Plain from 1961 to 2009 were examined.Trends of accumulated temperature and negative temperature,growing season duration,as well as seasonal and annual rainfalls at 48 stations were analyzed.The results show that the accumulated temperature increased significantly by 348.5℃ day due to global warming during 1961 2009 while the absolute accumulated negative temperature decreased apparently by 175.3℃ day.The start of growing season displayed a significant negative trend of-14.3 days during 1961-2009,but the end of growing season delayed insignificantly by 6.7 days.As a result,the length of growing sea.son increased by 21.0 days.The annual and autumn rainfalls decreased slightly while summer rainfall and summer rainy days decreased significantly.In contrast,spring rainfall increased slightly without significant trends.All the results indicate that the thermal conditions were improved to benefit the crop growth over the North China Plain during 1961-2009,and the decreasing annual and summer rainfalls had no direct negative impact on the crop growth.But the decreasing summer rainfall was likely to influence the water resources in North China,especially the underground water,reservoir water,as well as river runoff,which would have influenced the irrigation of agriculture.     

Spatiotemporal change in the climatic growing season in Northeast China during 1960–2009

Daily mean air temperatures from 81 meteorological stations in Northeast China were analyzed for the spatiotemporal change of the climatic growing season during the period 1960–2009. Our results showed that latitude strongly influenced the spatial patterns of the mean start (GSS), end (GSE), and length (GSL) of the growing season. For the area studied, a significant increasing trend in GSL during 1960–2009 was detected at a significance level of 0.01, especially after the early 1980s. The area-average GSL has extended 13.3 days during the last 50 years, mainly due to the advanced GSS evident in the spring (7.9 days). The variations of GSS and GSE were closely correlated with the monthly mean temperature (T _mean) of April and October, respectively, while GSL was closely related to the monthly minimum temperatures (T _min) of spring (March to April) and autumn (September to October). The distributions of the trends in growing season parameters (GSS, GSE, and GSL) showed great spatial variability over Northeast China. Significant relationships between altitude and the trend rates of the GSS and GSL were detected, while geographic parameters had little direct effect on the change in GSE. This extended growing season may provide favorable conditions for agriculture and forest, and improve their potential production.