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1.
中国地表气温变化对土地利用/覆被类型的敏感性 总被引:8,自引:0,他引:8
利用观测气温与再分析气温的差值分析了近40年中国地表气温变化对土地利用/覆被类型的敏感性.结果表明:土地利用/覆被类型对地表气温变化具有稳定的、系统性的影响,在全球变暖背景下各类型的响应不同,以沙地、戈壁和裸岩石砾地为主的未利用地升温幅度最大,为0.21℃/10a;其次是草地、耕地和城乡、工矿、居民用地,分别为0.12,0.10,0.12℃/10a;林地升温趋势最弱,为0.06℃/10a.总体来看,沙地、戈壁等未利用地和人类活动较多的区域地表升温幅度大,植被覆盖状况好的区域升温趋势则较弱;同一一级类型下理化特性及生物过程相似的二级类型对地表气温的影响程度相近,土地利用/覆被类型的变化需要达到一定的强度,导致地表特性发生本质改变后才会对局地气温产生较明显的影响;同一土地利用/覆被类型下,中国东部人类活动强度大的区域升温更为明显.这一结果为众多土地利用/覆被变化对气候影响的数值模拟试验研究提供了观测事实的支持.在区域尺度上预测未来中国气候变化不仅要考虑温室气体增加的影响,还要考虑土地利用/覆被类型及其变化的影响. 相似文献
2.
流域植被覆盖状况对于水源地生态环境保护具有重要的指示作用.当前的水质目标管理不仅要着眼于湖库水质参数控制,更应该从整个流域的角度维系生态平衡.在此背景下,依托长时间序列MODIS遥感数据对千岛湖流域2001-2013年植被覆盖状况进行监测,采用最小二乘法趋势分析和Mann-Kendall显著性检验方法分析了千岛湖流域植被的空间分布特征、时间变化特征与长期变化趋势.研究表明该方法能够有效地监测流域植被覆盖的时空动态变化:1)从空间分布上来看,千岛湖流域植被覆盖状况整体较好,但同时也发现受人为干扰较大的地域如河、湖附近的城镇建设用地、农业用地以及园地,其NDVI值明显低于自然林地;2)从时间变化特征上看,2001-2013年千岛湖流域植被年际NDVI在0.69~0.73之间波动,且近年来有增长趋势,年内季节性NDVI动态分析表明高时间分辨率的MODIS数据能够用来区分常绿植被与落叶植被的物候特征,以分析不同植被类型对流域氮、磷流失的风险差异;3)从变化趋势上看,2001-2013年植被覆盖状况改善的区域远大于退化的区域,其中改善区域约占流域面积的55.90%,呈现出一定退化状态的区域约占29.60%(严重退化区域仅占3.97%),而相对稳定不变区域约占14.51%.经与气温与降水等气候因子进行相关性分析表明,植被NDVI与气温呈显著正相关,而降水则不敏感,说明气温是研究区植被生长的主导气候因子.同时发现,人类活动对局部植被变化影响较大.研究结果可为流域水资源与生态环境保护提供空间数据支撑. 相似文献
3.
基于MODIS数据的博斯腾湖流域植被变化及其与气候因子的关系 总被引:1,自引:0,他引:1
以博斯腾湖流域为研究区,基于2001-2016年时间序列的MODIS NDVI数据分析了研究区植被的时空变化趋势,并结合流域气象站点的气温、降水、日照时数和相对湿度数据分析了植被生长季累积NDVI和16天NDVI与气候因子之间的响应特征.结果表明:(1)流域植被覆盖变化呈改善趋势,生长季累积NDVI年变化率为0.014 a-1,16天NDVI变化率均为正值,植被改善趋势显著区域主要分布在高山草原湿地和农业灌溉区边缘的新增农田.(2)植被生长季累积NDVI主要受降水和相对湿度影响,植被总体生产力与水分条件关系最密切,生长季逐16天NDVI与同期气温和日照时数在植被生长初期和末期关系显著,而与降水没有显著的相关性,说明植被短期瞬时长势对热量条件更为敏感.(3)在植被生长不同阶段对气候变化具有不同的滞后效应,其中植被生长初期和末期对气温有0.5~1个月的滞后,生长盛期对降水有0.5~3个月的滞后、日照时数有1.5~2.5个月的滞后、相对湿度有0.5~2.5个月的滞后,揭示了植被不同生长阶段水热条件对其生长韵律的控制差异. 相似文献
4.
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
5.
青藏高原植被变化与地表热源及中国降水关系的初步分析 总被引:4,自引:0,他引:4
利用设在青藏高原的5个自动气象站(AWS)近地层梯度观测资料、归一化植被指数(GIMMS NDVI)和中国624个台站月降水资料,初步分析了青藏高原植被变化与地表热源及中国降水的关系.结果表明:青藏高原植被与地表热源之间存在明显的正相关关系.高原西部感热与NDVI的正相关关系较高原东部显著,而高原东部地表潜热与NDVI的正相关关系则好于高原西部.植被改善后,各季节地表热源以增加为主,尤其夏季,热源增量最大;冬、春季感热对地表热源增量贡献较大,潜热贡献相对较小;夏、秋季感热与潜热对地表热源增量贡献同等重要.青藏高原植被与中国夏季降水相关系数从南到北,呈“+-+”带状分布.植被变化引起的高原地表加热异常可能是影响中国夏季降水的重要因子之一. 相似文献
6.
气候变化和人类活动对黄土高原植被覆盖变化的影响 总被引:24,自引:0,他引:24
利用GIMMS和SPOT VGT两种归一化植被指数(NDVI)数据对黄土高原地区1981~2006年期间植被覆盖的时空变化进行了研究, 并从气候变化和人类活动的角度分析了植被覆盖变化的原因. 黄土高原地区植被覆盖经历了以下4个阶段: ① 1981~1989年植被覆盖持续增加时期; ② 1990~1998年以小幅波动为特征的相对稳定时期; ③ 1999~2001年植被覆盖迅速下降时期; ④ 2002~2006年植被覆盖进入迅速上升时期. 黄土高原地区植被覆盖变化存在显著的空间差异, 内蒙古和宁夏沿黄农业灌溉区和鄂尔多斯退耕还林还草生态恢复区的植被覆盖明显提高, 而黄土丘陵沟壑区和六盘山、秦岭北坡等山地森林区的植被覆盖明显退化. 从不同的植被类型来看, 沙地、草地和耕地的NDVI上升趋势显著, 而森林植被的NDVI呈明显的下降趋势. 研究表明: 植被覆盖变化是气候变化和人类活动共同作用的结果. 黄土高原地区气候变暖在加剧土壤干燥化抑制夏季植被生长的同时, 提高了春、秋季节植被生长活性, 延长了植被生长期. 黄土高原地区植被覆盖和降水关系密切, 降水变化是植被覆盖变化的重要原因. 农业生产水平的提高致使农业区NDVI在不断上升, 同时, 正在黄土高原大规模进行的退耕还林还草工程建设, 其生态效应也正在呈现. 相似文献
7.
城市化引起的气温上升是土地覆盖变化影响区域气候的重要体现.本文采用“观测资料减去再分析”(Observation Minus Reanalysis,OMR)的方法估计四川盆地和周边地区下垫面城市化改变对夏季地面2 m气温变化趋势的影响.设计了不同城市化下垫面扩展变化的WRF模拟试验,对1998—2012年四川盆地及周边区域夏季逐日平均温度和日最高最低气温进行模拟.在检验模式模拟性能的基础上,利用OMR方法类似的思路定量探讨城市化下垫面对地面气温变化趋势的可能影响.结果显示,(1)基于站点观测资料的OMR分布表明成都、重庆地区的城市下垫面对夏季升温的影响可达0.1℃·a^-1;(2)WRF试验模拟的结果与实际观测接近,能较合理刻画出该地区夏季温度的平均分布及时间变化特征,可以用于该地区城市化区域气候效应的研究;(3)不同城市化进程的模式模拟试验中气温变化趋势的差值与基于站点观测的OMR方法计算得到的结果类似,都证明了重庆和成都的城市下垫面对地面2 m温度的升高具有显著影响,其中在日内低温的表现尤为突出. 相似文献
8.
青藏高原冻土区冻土与植被的关系及其对高寒生态系统的影响 总被引:11,自引:0,他引:11
选择高寒生态系统植被覆盖度、生物生产力和土壤养分与组成结构等要素和冻土环境的冻土上限深度、冻土厚度和冻土地温等指标, 分析了冻土环境与高寒生态系统之间的相互关系, 并基于气温与冻土温度间的统计模型, 建立了高寒生态系统对冻土环境变化的响应分析模型. 通过对青藏高原昆仑山-唐古拉山区域冻土环境要素在人类工程活动与气候变化双重作用下的变化及其对高寒生态系统的影响研究, 表明青藏高原冻土环境变化对高寒草甸和高寒沼泽草甸生态系统影响强烈, 随冻土上限深度增加, 高寒草甸植被覆盖度和生物生产量均呈现较为显著递减趋势, 并导致高寒草甸草地土壤有机质含量呈指数形式下降, 土壤表层砂砾石含量增加而显著粗砺化; 高寒草原生态系统与冻土环境的关系相对微弱; 全球气候变化及其作用下的冻土环境变化导致该区域近15年间高寒沼泽草甸生态系统分布面积锐减28.11%, 高寒草甸生态分布面积减少了7.98%. 在不同气温升高的情景下, 未来50年, 不同地貌单元的高寒草甸生态系统对冻土环境变化的响应程度不同, 其中位于低山和平原区的高寒草甸生态系统将产生较显著的退化, 从植被覆盖度和生物生产量两方面, 定量给出了不同气候变化情境下不同典型地区和地貌单元的高寒生态系统变化特征. 未来在工程活动中采取有效的冻土环境保护措施, 对高原冻土工程稳定性和维护高寒生态系统都具有重要意义. 相似文献
9.
北京城市及周边热岛日变化及季节特征的卫星遥感研究与影响因子分析 总被引:20,自引:0,他引:20
以EOS-MODIS遥感信息反演的地表温度、土地覆盖类型、植被覆盖、地表蒸散,结合常规气象资料,并采用GIS空间分析技术和多元统计相关,对北京城市及周边2001年城市热岛(UHI)空间分布的季节规律和日变化及影响因子进行研究.分析北京地区的土地覆盖、地形高程、植被绿地状况、城市和郊区地表蒸散与热岛时空分布状况的关系.揭示出北京UHI主要特征为:(ⅰ)北京城市下垫面的高热容和密集建筑物的多次发射,加之北京特殊的三面环山地形特征,使得北京城区一年四季均存在明显的热岛分布,并以夏季最为明显,UHI与城市结构的轮廓相一致;北京城区与地势相对平坦的近郊区的地表温度差异在4~6℃左右,与地势较高的西北远郊区的地表温度差异在8~10℃左右;(ⅱ)北京地区日间和夜晚的UHI的季节分布和程度不同,以夜间UHI明显;夏季白天郊区地表比城区蒸散量大,潜热交换明显,反映出城市与郊区的温度差异显著;(ⅲ)地表覆盖类型对UHI的效应明显,北京地区植被绿地状况与UHI呈现明显反相关分布;夏季地表NDVI与下垫面的温度散点图的回归方程的负相关系数的平方R2达到0.6481,即植被覆盖好,则UHI不明显;揭示出植被绿地对降低UHI具有重要的作用.大范围的绿地建设能有效降低UHI. 相似文献
10.
干旱是影响社会发展和农业生产的重要因素之一。本文基于EOS/MODIS卫星遥感资料,选取江西省2001-2006年的NDVI时间序列数据,分析了NDVI对干旱的响应规律。计算了NDVI与气温、降水之间的关系。并提取植被状态指数(VCI),分析VCI与气温距平、降水距平的空间分布规律。结果表明:2003年江西夏季旱灾以高温少雨天气为主。这一时期的NDVI数值明显低于其他年份同一时期的NDVI值。气温温度越高,NDVI值越大;日照时数时间越长,NDVI值越大;降水量越高,NDVI值越大;降水距平百分率越高,VCI值越高;平均温度距平越小,VCI值越高。说明气候因素对NDVI指数和VCI指数有很大影响。研究表明,基于MODIS的植被指数可以反映旱灾的时空分布规律。 相似文献
11.
XuChao Yang YiLi Zhang LinShan Liu Wei Zhang MingJun Ding ZhaoFeng Wang 《中国科学D辑(英文版)》2009,52(8):1207-1215
Using CRU high resolution grid observational temperature and ERA40 reanalysis surface air temperature data during 1960–1999,
we investigated the sensitivity of surface air temperature change to land use/cover types in China by subtracting the reanalysis
from the observed surface air temperature (observation minus reanalysis, OMR). The results show that there is a stable and
systemic impact of land use/cover types on surface air temperature. The surface warming of each land use/cover type reacted
differently to global warming. The OMR trends of unused land (⩾0.17 °C/decade), mainly comprised by sandy land, Gobi and bare
rock gravel land, are obviously larger than those of the other land use/cover types. The OMR over grassland, farmland and
construction land shows a moderate decadal warmingabout 0.12°C/decade, 0.10°C/decade, 0.12°C/decade, respectively. Woodland
areas do not show a significant warming trend (0.06°C/decade). The overall assessment indicates that the surface warming is
larger for areas that are barren and anthropogenically developed. The better the vegetation cover, the smaller the OMR warming
trend. Responses of surface air temperature to land use/cover types with similar physical and chemical properties and biological
processes have no significant difference. The surface air temperature would not react significantly until the intensity of
land cover changes reach a certain degree. Within the same land use/cover type, areas in eastern China with intensive human
activities exhibit larger warming trend. The results provide observational evidence for modeling research on the impact of
land use/cover change on regional climate. Thus, projecting further surface climate of China in regional scale should not
only take greenhouse gas increase into account, but also consider the impact of land use/cover types and land cover change.
Supported by National Basic Research Program of China (Grant No. 2005CB422006), National Natural Science Foundation of China
(Grant Nos. 90202012, 40771206) 相似文献
12.
Aierken Tuersun Yusufujiang Rusuli Aizezitiyuemaier Maimaiti Miriayi Maitudi Kadiayi Alimu 《洁净——土壤、空气、水》2020,48(5-6)
The Bosten Lake watershed investigated in this study has seen significant land cover and climate change. The spatiotemporal relationship between evapotranspiration (ET) and environmental factors remain unclear. In this study, trend analysis and correlation methods are applied to analyze the spatiotemporal characteristics of ET and the relationship between ET and its driving factors using remotely sensed ET data and measured climate data between 2001 and 2018. During the study period, high values of ET primarily occurr in the wetlands of the plain area and the mid‐elevation mountain areas. The ET values show a significantly increasing trend in the different vegetation types due to climate change and other factors. The ET change trend in the study area is in the range of ?13.4 to ≈35.9 mm per year; the desert area exhibits a significant decrease and most of the mountain areas show a significantly increasing trend. ET is significantly correlated with land surface temperature, normalized difference vegetation index (NDVI), and solar radiation. The dominant factor affecting ET is NDVI, accounting for 15.2% of the study area. The results of this study highlight the need for appropriate land‐use strategies for managing water resources in arid land ecosystems. 相似文献
13.
The temporal evolution of vegetation activity on various land cover classes in the Spanish Pyrenees was analyzed. Two time series of the normalized difference vegetation index (NDVI) were used, corresponding to March (early spring) and August (the end of summer). The series were generated from Landsat TM and Landsat ETM+ images for the period 1984–2007. An increase in the NDVI in March was found for vegetated areas, and the opposite trend was found in both March and August for degraded areas (badlands and erosion risk areas). The rise in minimum temperature and the time variation of the cloud cover during the study period appears to be the most important factors explaining increased NDVI in the vegetated areas. In degraded areas, no climatic or topographic variable was associated with the negative NDVI trend, which may be related to erosion processes taking place in these regions. Copyright © 2010 John Wiley & Sons, Ltd. 相似文献
14.
Spatiotemporal variations of vegetation cover on the Chinese Loess Plateau(1981―2006):Impacts of climate changes and human activities 总被引:1,自引:0,他引:1
Spatiotemporal variations of Chinese Loess Plateau vegetation cover during 1981-2006 have been investigated using GIMMS and SPOT VGT NDVI data and the cause of vegetation cover changes has been analyzed, considering the climate changes and human activities. Vegetation cover changes on the Loess Plateau have experienced four stages as follows: (1) vegetation cover showed a continued increasing phase during 1981―1989; (2) vegetation cover changes came into a relative steady phase with small fluctuations during 1990―1998; (3) vegetation cover declined rapidly during 1999―2001; and (4) vegetation cover increased rapidly during 2002―2006. The vegetation cover changes of the Loess Plateau show a notable spatial difference. The vegetation cover has obviously increased in the Inner Mongolia and Ningxia plain along the Yellow River and the ecological rehabilitated region of Ordos Plateau, however the vegetation cover evidently decreased in the hilly and gully areas of Loess Plateau, Liupan Mountains region and the northern hillside of Qinling Mountains. The response of NDVI to climate changes varied with different vegetation types. NDVI of sandy land vegetation, grassland and cultivated land show a significant increasing trend, but forest shows a decreasing trend. The results obtained in this study show that the spatiotemporal variations of vegetation cover are the outcome of climate changes and human activities. Temperature is a control factor of the seasonal change of vegetation growth. The increased temperature makes soil drier and unfavors vegetation growth in summer, but it favors vegetation growth in spring and autumn because of a longer growing period. There is a significant correlation between vegetation cover and precipitation and thus, the change in precipitation is an important factor for vegetation variation. The improved agricultural production has resulted in an increase of NDVI in the farmland, and the implementation of large-scale vegetation construction has led to some beneficial effect in ecology. 相似文献
15.
In this study, the vegetation dynamics and their correlations with climate variability in northern China were evaluated based on the normalized difference vegetation index (NDVI) and meteorological datasets from 1982 to 2006. The NDVI showed that vegetation cover had a tiny increasing trend for whole study area in the past 25 years. However, the interannual changes of NDVI were different in each season. The part of spring and autumn NDVI values increased significantly, while the summer NDVI increased no significantly. And the interannual variations of the NDVI showed obvious spatial differentiations. The annual max NDVI increased were mainly distributed in most areas of grassland and farmland, whereas the annual max NDVI decreased were mainly distributed in forest areas. The annual NDVI and temperature had more important relationships. Thus, as compared to precipitation, the correlation between NDVI with temperature was stronger than the precipitation in northern China. NDVI and climatic variables were different in each season. The NDVI trends exhibited a close correspondence to climatological variations in region and season. In Addition, human activities also had profound effect to the NDVI trends in some regions. All these findings will make humans know more about the knowledge of the natural forces that influence vegetation change and supply a scientific basic resource to for the environmental management in northern China. 相似文献
16.
Spatiotemporal variations of Chinese Loess Plateau vegetation cover during 1981–2006 have been investigated using GIMMS and
SPOT VGT NDVI data and the cause of vegetation cover changes has been analyzed, considering the climate changes and human
activities. Vegetation cover changes on the Loess Plateau have experienced four stages as follows: (1) vegetation cover showed
a continued increasing phase during 1981–1989; (2) vegetation cover changes came into a relative steady phase with small fluctuations
during 1990–1998; (3) vegetation cover declined rapidly during 1999–2001; and (4) vegetation cover increased rapidly during
2002–2006. The vegetation cover changes of the Loess Plateau show a notable spatial difference. The vegetation cover has obviously
increased in the Inner Mongolia and Ningxia plain along the Yellow River and the ecological rehabilitated region of Ordos
Plateau, however the vegetation cover evidently decreased in the hilly and gully areas of Loess Plateau, Liupan Mountains
region and the northern hillside of Qinling Mountains. The response of NDVI to climate changes varied with different vegetation
types. NDVI of sandy land vegetation, grassland and cultivated land show a significant increasing trend, but forest shows
a decreasing trend. The results obtained in this study show that the spatiotemporal variations of vegetation cover are the
outcome of climate changes and human activities. Temperature is a control factor of the seasonal change of vegetation growth.
The increased temperature makes soil drier and unfavors vegetation growth in summer, but it favors vegetation growth in spring
and autumn because of a longer growing period. There is a significant correlation between vegetation cover and precipitation
and thus, the change in precipitation is an important factor for vegetation variation. The improved agricultural production
has resulted in an increase of NDVI in the farmland, and the implementation of large-scale vegetation construction has led
to some beneficial effect in ecology.
Supported by the National Natural Science Foundation of China (Grant No. 40671019) and the Knowledge Innovation Project of
the Institute of Geographical Sciences and Natural Resources Research of Chinese Academy of Sciences 相似文献
17.
Kazuyoshi Suzuki Tetsuya Hiyama Koji Matsuo Kazuhito Ichii Yoshihiro Iijima Dai Yamazaki 《水文研究》2020,34(19):3867-3881
River runoff from the four largest Siberian river basins (the Ob, Yenisei, Lena, and Kolyma) considerably contributes to freshwater flux into the Arctic Ocean from the Eurasian continent. However, the effects of variation in snow cover fraction on the ecohydrological variations in these basins are not well understood. In this study, we analysed the spatiotemporal variability of the maximum snow cover fraction (SCFmax) in the four Siberian river basins. We compared the SCFmax from 2000 to 2016 with data in terms of monthly temperature and precipitation, night-time surface temperatures, the terrestrial water storage anomaly (TWSA), the normalised difference vegetation index (NDVI), and river runoff. Our results exhibit a decreasing trend in the April SCFmax values since 2000, largely in response to warming air temperatures in April. We identified snowmelt water as the dominant control on the observed increase in the runoff contribution in May across all four Siberian river basins. In addition, we detected that the interannual river runoff was predominantly controlled by interannual variations in the TWSA. The NDVI in June was strongly controlled by the timing of the snowmelt along with the surface air temperature and TWSA in June. The rate of increase in the freshwater flux from the four Siberian rivers decreased from 2000 to 2016, exhibiting large interannual variations corresponding to interannual variations in the TWSA. However, we identified a clear increase trend in the freshwater flux of ~4 km3/year when analysing the long-term 39-year historical record (1978–2016). Our results suggest that continued global warming will accelerate the transition towards the earlier timing of snowmelt and spring freshwater flux into the Arctic Ocean. Our findings also highlight the effects of earlier snowmelt on ecohydrological changes in the Northern Hemisphere. 相似文献
18.
The dynamic of vegetation coverage and its response to climate factors in Inner Mongolia, China 总被引:3,自引:2,他引:1
Yang Yang Jianhua Xu Yulian Hong Guanghui Lv 《Stochastic Environmental Research and Risk Assessment (SERRA)》2012,26(3):357-373
Normalized Difference Vegetation Index (NDVI) is widely recognized as a good indicator of vegetation productivity. Diagnosing
the NDVI trend and understanding climatic factors influences on NDVI can predict the productivity changes under different
climatic scenarios. This paper examined NDVI dynamic and its response to climate factors during a 10 year period (1998–2008)
in Inner Mongolia. The main findings are as follows: (1) The NDVI multi-scale characters can be revealed well by wavelet transform,
and the average NDVI and the NDVI amplitude show a gradually decreased trend from northeast to southwest in Inner Mongolia
during the past 10 years, furthermore, this trend is consistent with the heat and water distribution caused by latitude difference
in north–south direction and Asia monsoon effect in east–west direction. (2) The relation between NDVI and temperature is
the most close, followed by precipitation, sunshine hours and relative humidity. Different vegetation cover types show different
strengths in correlation between NDVI and climate variables with the correlation values decreasing from forest, meadow steppe
to desert steppe in whole. (3) The precipitation and temperature have the same change cycle, both nearly 290 days in the 20
selected stations. The NDVI has the same change cycle with the precipitation and temperature or either 10 days earlier or
later than precipitation and temperature, which supports the significant correlation between NDVI and its climatic factors
from a new perspective. The nearly 290 days change cycle implies that the vegetation growth cycle is nearly 10 months and
there are no obvious differences change cycles in different vegetations. (4) Vegetation dynamic is significantly correlated
to the temperature and precipitation at the time scale of 10, 20, 40, 80, 160, and 320-day, respectively, and the S3 scale
(i.e., the time scale of 80-day), nearly 3 months (one season), is most significant and suitable for evaluating the vegetation
dynamic to climatic factors. 相似文献
19.
Air temperature feedback results from the thermal-radiative coupling between the atmosphere and the surface and plays an important role in surface energy balance. This paper reveals the contribution of air temperature feedback to the global warming from 1980 to 2000. The air temperature feedback kernel, evaluated using the ERA-Interim reanalysis data, is used to discuss the physical mechanism for air temperature feedback, the dependency of the strength of air temperature feedback on the climatological spatial distributions of air temperature, water vapor and cloud content, and the contributions of air temperature feedback to rapid global warming. The coupling between temperature feedback and each of the external forcings and individual feedback processes will amplify the anomaly of direct energy flux convergence at the surface induced by the external forcings and individual processes. The air temperature feedback amplifies the initial surface warming due to the increase in CO2 concentration, ice and snow melting, increase in water vapor, and change in ocean heat storage. It also amplifies the surface warming due to the longwave radiaitve forcing associated with the increase in cloud cover, which acts to suppress the cooling of the shortwave effect of cloud forcing. Overall, temperature feedback plays an important role in the global warming from 1980 to 2000, as the net positive contribution to the perturbation of global mean energy flux at the surface from the air temperature feedback is larger than the net negative contribution from external forcing and all non-temperature feedbacks. 相似文献