秦岭森林物候时空分布特征及对水热条件的响应

doi:10.12118/j.issn.1000-6060.2019.05.10

摘要/Abstract

摘要：

大量观测数据分析表明，全球气候正逐步变暖。植物物候现象是全球自然环境变化的指示器。物候对气候变化的响应是研究全球气候变化的重要手段之一。森林是全球生态系统的重要组成部分，森林物候特征变化是反映气候变化对森林生长影响的综合性生物指标。利用2001—2018年MOD09A1卫星数据重建了秦岭地区增强型植被指数（EVI）序列，采用最大变化速率和阈值法结合提取了秦岭森林物候参数，结果表明：（1） Whittaker滤波法在灌木、农田、森林3种生态样地重建中稳定性较好，在秦岭山地有较好的适用性。（2）秦岭地区物候多年均值分布同秦岭地区水热条件密切，由高海拔高山区到农耕区，生长季始期(Start of Growth Season,SOG)逐渐提前，生长季末期(End of Growth Season,EOG)逐渐推迟，生长季长度(Length of Growth Season,LOG)由高海拔区向低海拔区逐渐加长。秦岭浅山区和东部伏牛山农耕带生长季（SOG）开始较早，出现在3月上旬，高山区针叶林带生长季开始的较晚，出现在5月上旬到中旬（120～135 d）之间。生长季末期（EOG）集中出现在10月~11月初（270～310 d），高山区针叶林带生长季结束较早，浅山区植被生长季结束较晚，普遍出现在11月（300 d）以后。生长季长度（LOG）分布在150～200 d之间，低海拔地区LOG较长，大于180 d，高海拔林区生长季较短LOG集中在150～170 d。（3）年际变化特征：2001—2018年生长季始期（SOG）呈现提前趋势,其中高海拔区提前明显，南北麓海拔低于500 m部分区域和东部伏牛山少部分区域出现推迟。生长季末期（EOG）呈现推迟趋势，其中秦岭北麓和东部中低海拔区域推迟明显，生长期长度（LOG）总体呈延长趋势。（4）秦岭地区近17 a气温呈现上升趋势，变化率为0.02 ℃·a^-1，降水呈现不明显的上升趋势，日照时数则呈现明显的下降趋势，变化率为14.6 h·a^-1。（5）秦岭地区物候参数同0 ℃、5 ℃和10 ℃界限温度、降水、日照时数相关性分析表明，全球变化下的升温作用是影响秦岭森林物候变化的主要因子，升温作用导致SOG提前，EOG推迟、LOG延长，主要集中在秦岭南北麓1 000~2 000 m之间，秦岭东部伏牛山低海拔区境内相关性最低，表明受温度制约较小。

关键词: 秦岭, 物候, 生长季末期（EOG）, 生长季始期（SOG）, 生长季长度（LOG）

Abstract:

Based on the product of C5 MOD09A1 from Land Processes Distributed Active Center (NASA LPACC) from 2001 to 2018,the Enhanced Vegetation Index (EVI) over Qinling Mountains,the geographical boundary of south-north China,is reconstructed.The four reconstruction methods,Whittaker,DL,HANTS and AG algorithms were evaluated.Then the phenological parameters of Qinling Mountains was extracted with the maximum change rate and threshold method. We got the followed results.The Whittaker filter method is generally the best among the four methods in reconstructing the EVI of shrubs,fields and forests over Qinling Mountains.And the EVI from the Whittaker filter method shows the lowest difference from the original EVI in the reconstruction of shrub,farmland and forest cover with higher representative than that from the DL,AG and HANTS algorithms. Along the main ridge of the Qinling Mountains from the high elevations to the farming area,the start of growth season is gradually moved earlier,the end of growth season is gradually delayed and the length of growth seasons become much longer.The growing season in the northern and southern shallow-mountain areas and Funiu Mountains starts in early March,while it begins in early and mid-May (120-135 d of the year) in the coniferous forest belt.While the end of growth season in the coniferous forest belt ends earlier than that of shallow-mountain areas which mainly appear in early of November,and both of them is mainly in the range of 270-310 d of the year.The length of the growth (LOG) season over Qinling Mountains is mainly about 150-200 d,and the LOG at lower elevation (about 180 d) is longer than that of forest regions at higher elevation which is about 150-170 d.The distribution of the initial period of SOG over 95% areas of the Qinling Mountains generally shows an advance of 1-2 d,especially for the high-altitude area,which shows an obvious advance trend with about 2 d·a^-1,while there is a delay trend over the areas with the elevation lower than 500 m and the Funiu mountains.There is a delayed trend of the growth seasons (EOG) over Qinling Mountains,especially over the north of Qinling Mountains and low-altitude areas (about 2-3 d·a^-1).Furthermore,the length of growth seasons over Qinling Mountains become longer,and the change range of 72% of the forest is about 1-23 d·a^-1. There is a slightly increased trend of average temperature with a rate of 0.02 ℃·a^-1,while the total annual sunshine duration is decreased with a rate of 14.6 h·a^-1 over the Qinling Mountains.The change of hydrothermal conditions further affected the phenological parameters of Qinling Mountains.The correlation analysis between accumulated temperature,total precipitation and total sunshine duration and the phenological parameters at the temperatures of 0 ℃,5 ℃ and 10 ℃ respectively,which shows that the response sequence of the phenological parameters to the three climatic factors is: accumulated temperature> precipitation>sunshine.The increasing of temperature slightly leads to an earlier SOG,a delayed EOG and a longer LOG,especially in the areas with the elevation between 1 000 and 2 000 m over the southern and northern part of Qinling Mountains.While for higher mountains the correlations becomes more complex.The response of phenological parameters to accumulated temperature over Funiu Mountains in the east of Qinling Mountains is not obvious and there may be some other restriction factors.

Key words: Qinling Mountains, phenological parameters, EOG, SOG, LOG

王钊, 彭艳, 权文婷, 何慧娟, 李登科. 秦岭森林物候时空分布特征及对水热条件的响应[J]. 干旱区地理, 2019, 42(5): 1048-1058.

WANG Zhao, PENG Yan, QUAN Wen-ting, HE Hui-juan, LI Deng-ke. Characteristic of plant phenology and its response to the hydrothermal conditions over Qinling Mountains[J]. Arid Land Geography, 2019, 42(5): 1048-1058.

参考文献［52］

［1］	PING Y P,ZANG S Y.Crop identification based on MODIS NDVI time-series data and phenological characteristics［J］.Journal of Natural Resources,2016,31(3):503-513.
［2］	HE Y,FAN G F,ZHANG X W,et al.Vegetation phenological variation and its response to climate changes in Zhejiang Province［J］.Journal of Natural Resources,2013,28(2):220-233.
［3］	ATZBERGR C,EILERS P H C.A time series for monitoring vegetation activity and phenology at 10-daily time steps covering large parts of South America［J］.International Journal of Digital Earth,2011,4(5):365-386.
［4］	BECK P S A,ATZBERGR C,HOGDA K A.Improved monitoring of vegetation dynamics at very high latitudes:A new method using MODIS NDVI［J］.Remote Sensing of Environment,2006,100(3):321-334.
［5］	SAKAMOTO T,YOKOZAWA M,TORITANI H.A crop phenology detection method using timeseries MODIS data［J］.Remote Sensing of Environment,2005,96(3):366-374.
［6］	CHEN J,JNSSON P,TAMURA M.A simple method for reconstructing a highquality NDVI time-series data set based on the Savitzky-Golay filter［J］.Remote Sensing of Environment,2004,91(3):332-344.
［7］	JULIEN Y,SOBRINO J A.Global land surface phenology trends from GIMMS database［J］.International Journal of Remote Sensing,2009,30:3495-3513.
［8］	WANG G C,CAO R Y,CHEN J,RAO Y.Temperature sensitivity of spring vegetation phenology correlates to within-spring warming speed over the Northern Hemisphere［J］.Ecological Indicators,2015.50(3):62-68.
［9］	WHITE M A,DEBEURS K M,DIDAN K.Intercomparison,interpretation,and assessment of spring phenology in North America estimated from remote sensing for 1982—2006［J］.Global Change Biology,2009,15:2335-2359.
［10］	ZHANG X Y,FRDED M A,SCHAAF C B.Monitoring vegetation phenology using MODIS［J］.Remote Sensing of Environment,2003,84:471-475.
［11］	LLOYD D A.Phenological classification of terrestrial vegetation cover using shortwave vegetation index imagery［J］.INT J Remote Sense,1990,11:2269-2279.
［12］	FISHER J I,MUSTARD J F.Cross-scalar satellite phenology from ground,Landsat and MODIS data［J］.Remote Sensing of Environmen,2007,109(3):261-273.
［13］	KROSS A,FERNANDES R,SEAQUIST J,et al.The effect of the temporal resolution of NDVI data on season onset dates and trends across Canadian broadleaf forests［J］.Remote Sensing of Environment,2011,115(6):1564-1575.
［14］	PIAO S L,CIAIS P.Net carbon dioxide losses of northern ecosystems in response to autumn warming［J］.Nature,2008,451:49-52.
［15］	ATKINSON P M,JEGANATHAN C,DASH J,et al.Inter-comparison of four models for smoothing satellite sensor time-series data to estimate vegetation phenology［J］.Remote Sensing of Environment,2012,123(8):400-417.
［16］	方修琦,余卫红.物候对全球变暖响应的研究综述［J］.地球科学进展,2002,17(5):714-719.［FANG Xiuqi,YU Weihong.Progress in the studies on the phenological responding to global warming［J］.Advances in Earth Science,2002,17(5):714-719.］
［17］	郑景云,葛全胜,郝志新.气候增暖对我国近40年植物物候变化的影响［J］.科学通报,2002,47(20):1582-1587.［ ZHENG Jingyun,GE Quansheng,HAO Zhixin.Effects of global warming on plant phenological changes for the last 40 years in China［J］.Chinese Science Bulletin,2002,47(20):1584-1587.］
［18］	张学霞,葛全胜,郑景云.北京地区气候变化和植被的关系——基于遥感数据和物候资料的分析［J］.植物生态学报,2004,28(4):499-506.［ ZHANG Xuexia,GE Quansheng,ZHENG Jingyun.Relationships between climate change and vegetation in Beijing using remote sensed data and phonological data［J］.Chinese Journal of Plant Ecology,2004,28(4):499-506.］
［19］	陆佩玲,于强,贺庆棠.植物物候对气候变化的响应［J］.生态学报,2006,26:923-929.［LU Peiling,YU Qiang,HE Qingtang.Responses of plant phenology to climatic change［J］.Acta Ecologica Sinica,2006,26(3):923-929.］
［20］	李明,吴正方,杜海波,等.基于遥感方法的长白山地区植被物候期变化趋势研究［J］.地理科学.2011,31(10):1242-1248.［LI Ming,WU Zhengfang,DU Haibo,et al.Growing-season trends determined from SPOT NDVI in Changbai Mountains,China,1999—2008［J］.Scientia Geographic Sinica,2011,31(10):1242-1248.］
［21］	何月,樊高峰,张小伟,等.浙江省植被物候变化及其对气候变化的响应［J］.自然资源学报,2013,28(2):220-233.［HE Yue,FAN Gaofeng,ZHANG Xiaowei,et al.Vegetation phenological variation and its response to climate changes in Zhejiang Province［J］.Journal of Natural Resources,2013,28(2):220-233.］
［22］	王连喜,陈怀亮,李琪,等.植物物候与气候研究进展［J］.生态学报,2010,30(2):447-454.［WANG Lianxi,CHEN Huailiang,LI Qi,et al.Research advances in plant phenology and climate［J］.Acta Ecological Sinica,2010,30(2):447-454.］
［23］	仲舒颖,郑景云,葛全胜.近40年中国东部木本植物秋季叶全变色期变化［J］.中国农业气象,2010,31(1):1-4.［ZHONG Shuying,ZHENG Jingyun,GE Quansheng.Change of autumnal leaf coloring of woody plants in Eastern China for the last 40 years［J］.Chinese Journal of Agrometeorology,2010,31(1):1-4.］
［24］	王传海,吴飞倩,李淑娟.西安植物园木本植物近十余年物候变化的特征分析［J］.中国农业气象,2006,27(4):261-264.［WANG Cuanhai,WU Feiqian,LI Shujuan.Phenological changes of ligneous plants in Xi’an Botanic Garden in last 15 years［J］.Chinese Journal of Agrometeorology,2006,27(4):261-264.］
［25］	谢宝妮,秦占飞,王洋,等.基于遥感的黄土高原植被物候监测及其对气候变化的响应［J］.农业工程学报,2015,31(15):153-160.［XIE Baoni,QIN Zhanfei,WANG Yang,et al.Monitoring vegetation phenology and their response to climate change on Chinese Loess Plateau based on remote sensing［J］.Transactions of the Chinese Society of Agricultural Engineering,2015,31(15):153-160.］
［26］	李登科,范建忠,权文婷.陕西省植被退化及其驱动因素分析［J］.生态学杂志,2015,34(10):2907-2913.［ LI Dengke,FAN Jianzhong,QUAN Wenting.Analysis of vegetation degradation and its driving factors in Shaanxi Province［J］.Chinese Journal of Ecology,2015,34(10):2907-2913.］
［27］	宋辉,刘康,范亚宁.秦岭山地森林退化时空变化分析［J］.中国人口资源与环境,2016,5:153-157.［ SONG Hui,LIU Kang,FAN Yaning.China forest degradation spatial and temporal variation analysis of Qinling Mountains［J］.Population,Resources and Environment,2016,5:153-157.］
［28］	夏浩铭,李爱农,赵伟,等.2015、2001—2010年秦岭森林物候时空变化遥感监测［J］.地理科学进展,34(10):1297-1305.［XIA Haoming,LI Ainong,ZHAO Wei,et al.Spatiotemporal variations of forest phenology in the Qinling zone based on remote sensing monitoring 2001—2010［J］.Progress in Geography,2015,34(10):1297-1305.］
［29］	贺映娜.秦岭植被物候期及遥感生长季的变化研究［D］.西安:西北大学,2012.［HE Yingna.Research on the variatition of vegetation phenology in Qinling Moutain base on remote sensing and in situ obersation［D］.Xi’an:Northwest University,2012.］
［30］	张晗,任志远.基于Whittaker滤波的陕西省植被物候特征［J］.中国沙漠,2015,35(4):901-903.［ZHANG Han,REN Zhiyuan.Remote sensing analysis of vegetation phenology characteristics in Shaanxi Province based on Whittaker smoother method［J］.Journal of Desert Research,2015,35(4):901-906.］
［31］	张殷波,郭柳琳,王伟.秦岭重点保护植物丰富度空间格局与热点地区［J］.生态学报,2014,34(8):2109-2117.［ZHANG Yinbo,GUO Liulin,WANG Wei,et al.Spatial distribution patterns of species richness and hotspots of protected plants in Qinling Mountain［J］.Acta Ecologica Sinica,2014,34(8):2109-2117.］
［32］	尚升海,邢海.秦岭南北坡植被垂直分布的差异比较［J］.园林生态.2016,1(1):114-115.［SHANG Shenghai,XING Hai,Comparison of vertical distribution of vegetation on north and south slopes of Qinling Mountains［J］.landscape and Ecology,2016,1(1):114-115.］
［33］	杨嘉,郭铌,黄蕾诺,等.西北地区MODIS-NDVI指数饱和问题分析［J］.高原气象,2008,27 (4):896-903.［YANG Jia,GUO Ni,HUANG Leinuo,et al.Analyses on MODISNDVI Index Saturation in Northwest China［J］.Plateau Meteor,2008,27(4):896-903.］
［34］	刘亚南,肖飞,杜耘.基于秦岭样区的四种时序EVI函数拟合方法对比研究［J］.生态学报.2016,36(15):4672-4679.［LIU Yanan,XIAO Fei,DU Yun.Analysis of four time series EVI data reconstruction methods［J］.Acta Ecologica Sinica,2016,36(15):4672-4679.］
［35］	宋春桥,柯灵红,游松财.基于TIMESAT的3种时序NDVI拟合方法比较研究——以藏北草地为例［J］.遥感技术与应用.2011,26(2):147-155.［SONG Chunqiao,KE Linghong,YOU Songcai.Comparison of three NDVI time-series fitting methods based on TIMESAT:Taking the grass land in Northern Tibetan as case［J］.Remote Sensing Technology and Application,2011,26(2):147-155.］
［36］	CHEN J,JNSSOM P,TAMURA M,et al.A simple method for reconstructing a highquality NDVI time-series data set based on the Savitzky-Golay filter ［J］.Remote Sensing of Environment,2004.91(3-4):332-344.
［37］	李杭燕,颉耀文,马明国.时序NDVI数据集重建方法评价与实例研究［J］.遥感技术与应用,2009,24(5):596-602.［LI Hangyan,XIE Yaowen,MA Mingguo.Reconstruction of temporal NDVI dataset:Evaluation and case study［J］.Remote Sensing Technology and Application,2009,24(5):596-602.］
［38］	王乾坤,于信芳,舒清态,等.MODIS EVI时序数据重建方法及拟合分析［J］.地球信息科学学报,2015,17(6):732-741.［WANG Qiankun,YU Xinfang,SHU Qingtai,et al.Comparison on three algorithms of reconstructing time-series MODISEVI［J］.Journal of Geo-Information Science,2015,17(6):732-741.］
［39］	周惠慧,王楠,黄瑶,等.不同时间间隔下的遥感时间序列重构模型比较分析［J］.地球信息科学学报,2016,18(10):1410-1417.［ZHOU Huihui,WANG Nan,HUANG Yao,et al.Comparison and analysis of remotely sensed time series of reconstruction models at various intervals［J］.Journal of Geo-information Science,2016,18 (10):1410-1417.］
［40］	刘玲玲,刘良云,胡勇.1982—2006年欧亚大陆植被生长季开始时间遥感监测分析［J］.地理科学进展,2012,31(11):1433-1442.［LIU Lingling,LIU Liangyun,HU Yong.Assessment and intercomparison of satellite-derived start-of-season (SOS) measures in Eurasia for 1982—2006［J］.Progress in Geography,2012,31(11):1433-1442.］
［41］	丁明军,张镱锂,孙晓敏,等.近10年青藏高原高寒草地物候时空变化特征分析［J］.科学通报,2012,57(33):3185-3194.［DING Mingjun,ZHANG Yili,SUN Xiaomin,et al.Spatiotemporal variation in alpine grassland phenology in the Qinghai-Tibetan Plateau from 1999 to 2009 ［J］.Chinese Science Bulletin,2012,58(3):396-405.］
［42］	范德芹,赵学胜,朱文泉,等.植物物候遥感监测精度影响因素研究综述［J］.地理科学进展,2016,35(3):304-319.［FAN Deqin,HAO Xuesheng,ZHU Wenquan,et al.Review of influencing factors of accuracy of plant phenology monitoring based on remote sensing data［J］.Progress in Geography,2016,35(3):304-319.］
［43］	曹沛雨,张雷明,李胜功,等.植被物候观测与指标提取方法研究进展［J］.地球科学进展,2016,31(4):365-376.［ CAO Peiyu,ZHANG Leiming,LI Shenggong,et al.Review on vegetation phenology observation and phenological index extraction［J］.Advanced Earth Science,2016,31(4):365-376.］
［44］	白洁,葛全胜,戴君虎.西安木本植物物候与气候要素的关系［J］.植物生态学报,2010,34(11):1274-1282.［BAI Jie,GE Quansheng,DAI Junhu,et al.Relationship between woody plants phenology and climate factors in Xi’an,China［J］.Chinese journal of Plant Ecology,2010,34(11):1274-1282.］
［45］	李双双,延军平,万佳.全球气候变化下秦岭南北气温变化特征［J］.地理科学,2012,32(7):853-858.［LI Shuangshuang,YAN Junping,WAN Jia.The characteristics of temperature change in Qinling Mountains［J］.Scientia Geographica Sincia,2012,32(7):853-858.］
［46］	韦振锋,任志远,张翀.1999—2010年陕甘宁黄土高原区气候对植被物候的影响［J］.水土保持通报,2014,34(5):232-236.［WEI Zhenfeng,REN Zhiyuan,ZHANG Chong.Impact of climate on vegetation phenology on Loess Plateau in Shaanxi-Gansu-Ningxia Region during 1999—2010［J］.Bulletin of Soil and Water Conservation,2014,34(5):232-236.］
［47］	王钊,罗慧,李亚丽,等.近50年秦岭南北不均匀增温及对城市化响应［J］.应用气象学报,2016,(1):84-94.［WANG Zhao,LUO Hui,LI Yali,et al.Effects of Urbanization on Temperatures over the Qinling Mountains in the Past 50 Years［J］.Quarterly Journal of Applied Meteorology,2016,(1):84-94.］
［48］	王钊,彭艳,魏娜.近52 a秦岭南北极端温度变化及其与区域增暖的关系［J］.干旱气象,2016,34(2):269-275.［WANG Zhao,PENG Yan,WEI Na.Variation trends of the extreme temperature and its relationship with regional warming in the South and North sides of the Qinling Mountain during 1961—2012［J］.Arid Meteorology,2016,34(2):269-275.］
［49］	周旗,卞娟娟,郑景云.秦岭南北1951—2009年的气温与热量资源变化［J］.地理学报,2011,66(9):1211-1218.［ZHOU Qi,BIAN Juanjuan,ZHENG Jingyun.Variation of air temperature and thermal resources in the Northern and Southern regions of the Qinling Mountains from 1951 to 2009［J］.Acta Geographica Sinica,2011,66(9):1211-1218.］
［50］	张立伟,宋春英,延军平.秦岭南北年极端气温的时空变化趋势研究［J］.地理科学,2011,31(8),1007-1011.［ZHANG Liwei,SONG Chunying,YAN Junping.Spatiotemporal trends of annual extreme temperature in Northern and Southern Qinling Mountains［J］.Scientia Geographica Sinca,2011,31(8):1007-1011.］
［51］	彭艳,王钊.1960—2012年陕西降水变化特征及可能成因分析［J］.高原气象,2016,35(4):1050-1059. ［PENG Yan,WANG Zhao,DONG Yan,et al.Characteristics and reasons of local changing of precipitation over Shaanxi during 1960—2012［J］.Plateau Meteor,2016,35(4):1050-1059．］
［52］	王晓玲,任燕.秦岭山区近 50 年降水差异及可能局地成因探讨［J］.气候与环境研究,2012,17(6):911-918.［WANG Xiaoling,REN Yan.Analysis of precipitation differences and their local causes in the last 50 years around the Qinling Mountains［J］.Climatic & Environmental Research,2012,17(6):911-918.］

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