[1] Lucht W, Prentice I C, Myneni R B et al. Climatic control of the high-latitude vegetation greening trend and Pinatubo effect[J]. Science, 296, 1687-1689(2002).

[6] Keenan T F, Gray J, Friedl M A et al. Net carbon uptake has increased through warming-induced changes in temperate forest phenology[J]. Nature Climate Change, 4, 598-604(2014).

[8] Myneni R B, Keeling C D, Tucker C J et al. Increased plant growth in the northern high latitudes from 1981 to 1991[J]. Nature, 386, 698-702(1997).

[9] Richardson A D, Keenan T F, Migliavacca M et al. Climate change, phenology, and phenological control of vegetation feedbacks to the climate system[J]. Agricultural and Forest Meteorology, 169, 156-173(2013).

[10] Goetz S J, Epstein H E, Bhatt U S et al. Recent changes in Arctic vegetation: Satellite observations and simulation model predictions//Gutman G, Reissell A. Eurasian Arctic Land Cover and Land Use in a Changing Climate. Amsterdam,[J]. Netherlands: Springer, 9-36(2011).

[11] Zhang K, Kimball J S, Mu Q Z et al. Satellite based analysis of northern ET trends and associated changes in the regional water balance from 1983 to 2005[J]. Journal of Hydrology, 379, 92-110(2009).

[12] Buermann W, Bikash P R, Jung M et al. Earlier springs decrease peak summer productivity in North American boreal forests[J]. Environmental Research Letters, 8, 24-27(2013).

[13] Reed B C, Brown J F, Vanderzee D et al. Measuring phenological variability from satellite imagery[J]. Journal of Vegetation Science, 5, 703-714(1994).

[14] Hudson I L, Keatley M R. Phenological Research: Methods for Environmental and Climate Change Analysis[J]. Amsterdam, Netherland: Springer(2010).

[16] Dragoni D, Rahman A F. Trends in fall phenology across the deciduous forests of the eastern USA[J]. Agricultural and Forest Meteorology, 157, 96-105(2012).

[17] Hmimina G, Dufrêne E, Pontailler J Y et al. Evaluation of the potential of MODIS satellite data to predict vegetation phenology in different biomes: An investigation using ground-based NDVI measurements[J]. Remote Sensing of Environment, 132, 145-158(2013).

[18] Fisher J I, Richardson A D, Mustard J F. Phenology model from surface meteorology does not capture satellite-based greenup estimations[J]. Global Change Biology, 13, 707-721(2006).

[19] Zhang X, Friedl M A, Schaaf C B et al. Monitoring vegetation phenology using MODIS[J]. Remote Sensing of Environment, 84, 471-475(2003).

[27] Tucker C J, Pinzon J E, Brown M E et al. An extended AVHRR 8-km NDVI dataset compatible with MODIS and SPOT vegetation NDVI data[J]. International Journal Remote Sensing, 26, 4485-4498(2005).

[28] Beck H E, McVicar T R, van Dijk A I J M et al. Global evaluation of four AVHRR-NDVI data sets: Intercomparison and assessment against Landsat imagery[J]. Remote Sensing of Environment, 115, 2547-2563(2011).

[30] Wang J, Dong J, Yi Y et al. Decreasing net primary production due to drought and slight decreases in solar radiation in China from 2000 to 2012[J]. Journal of Geophysical Research: Biogeosciences, 122, 261-278(2017).

[31] Beck P S A, Atzberger C, Høgda K A et al. Improved monitoring of vegetation dynamics at very high latitudes: A new method using MODIS NDVI[J]. Remote Sensing of Environment, 100, 321-334(2006).

[33] Piao S L, Yin G D, Tan J G et al. Detection and attribution of vegetation greening trend in China over the last 30 years[J]. Global Change Biology, 21, 1601-1609(2015).

[34] Fu Z, Dong J W, Zhou Y K et al. Long term trend and interannual variability of land carbon uptake: The attribution and processes[J]. Environment Research Letters, 12, 014018(2017).

[36] Groemping U. Relative importance for linear regression in R: The Package relaimpo[J]. Journal of Statistical Software, 17, 1-27(2006).

[37] Huang K, Xia J Y, Wang Y P et al. Enhanced peak growth of global vegetation and its key mechanisms[J]. Nature Ecology & Evolution, 2, 1897-1905(2018).

[38] Zhu W Q, Tian H Q, Xu X F et al. Extension of the growing season due to delayed autumn over mid and high latitudes in North America during 1982-2006[J]. Global Ecology and Biogeography, 21, 260-271(2012).

[39] Wu C Y, Wang X J, Wang H J et al. Contrasting responses of autumn-leaf senescence to daytime and night-time warming[J]. Nature Climate Change, 8, 1092-1096(2018).

[40] Buermann W, Forkel M, O’Sullivan M et al. Widespread seasonal compensation effects of spring warming on northern plant productivity[J]. Nature, 562, 110-114(2018).

[41] Forkel M, Carvalhais N, Rödenbeck C et al. Enhanced seasonal CO₂ exchange caused by amplified plant productivity in northern ecosystems[J]. Science, 351, 696-699(2016).

[42] Gonsamo A, Chen J M, Ooi Y W. Peak season plant activity shift towards spring is reflected by increasing carbon uptake by extratropical ecosystems[J]. Global Change Biology, 24, 2117-2128(2018).

[43] Wu D H, Zhao X, Liang S L et al. Time-lag effects of global vegetation responses to climate change[J]. Global Change Biology, 21, 3520-3531(2015).

[44] Ahlström A, Raupach M R, Schurgers G et al. The dominant role of semi-arid ecosystems in the trend and variability of the land CO₂ sink[J]. Science, 348, 895-899(2015).

[45] Gilmanov T G, Tieszen L L, Wylie B K et al. Integration of CO₂ flux and remotely-sensed data for primary production and ecosystem respiration analyses in the Northern Great Plains: Potential for quantitative spatial extrapolation[J]. Global Ecology and Biogeography, 14, 271-292(2005).

[47] Zhang X Y, Liu L L, Henebry G M. Impacts of land cover and land use change on long-term trend of land surface phenology: A case study in agricultural ecosystems[J]. Environmental Research Letters, 14, 044020(2019).