Abstract
As an important part of a terrestrial ecosystem, vegetation plays an important role in the global carbon-water cycle and energy flow. Based on the Global Inventory Monitoring and Modeling System (GIMMS) third generation of Normalized Difference Vegetation Index (NDVI3g), meteorological station data, climate reanalysis data, and land cover data, this study analyzed the climate dynamics of the spatiotemporal variations of vegetation NDVI in northern China from 1982 to 2015. The results showed that growth season NDVI (NDVIgs) increased significantly at 0.006/10a (p < 0.01) in 1982–2015 on the regional scale. The period from 1982 to 2015 was divided into three periods: the NDVIgs increased by 0.026/10a (p < 0.01) in 1982–1990, decreased by −0.002/10a (p > 0.1) in 1990–2006, and then increased by 0.021/10a (p < 0.01) during 2006–2015. On the pixel scale, the increases in NDVIgs during 1982–2015, 1982–1990, 1990–2006, and 2006–2015 accounted for 74.64%, 85.34%, 48.14%, and 68.78% of the total area, respectively. In general, the dominant climate drivers of vegetation growth had gradually switched from solar radiation, temperature, and precipitation (1982–1990) to precipitation and temperature (1990–2015). For woodland, high coverage grassland, medium coverage grassland, low coverage grassland, the dominant climate drivers had changed from temperature and solar radiation, solar radiation and precipitation, precipitation and solar radiation, solar radiation to precipitation and solar radiation, precipitation, precipitation and temperature, temperature and precipitation. The areas controlled by precipitation increased significantly, mainly distributed in arid, sub-arid, and sub-humid areas. The dominant climate drivers for vegetation growth in the plateau climate zone or high-altitude area changed from solar radiation to temperature and precipitation, and then to temperature, while in cold temperate zone, changed from temperature to solar radiation. These results are helpful to understand the climate dynamics of vegetation growth, and have important guiding significance for vegetation protection and restoration in the context of global climate change.
Highlights
Climate change has a significant impact on the structure and function of global ecosystem [1,2]
The results show that the influence of solar radiation on vegetation growth increases gradually in the northern high latitude region, while the effect of temperature decreases gradually, which is opposite in plateau climate region
We focused on the change of vegetation growth in WL, high coverage grassland (HCG), medium coverage grassland (MCG), and low coverage grassland (LCG), and did not analyze the transfer of four vegetation types in different periods
Summary
Climate change has a significant impact on the structure and function of global ecosystem [1,2]. The increase in temperature and the decrease in precipitation lead to serious drought, which will be more serious and frequent in the 21st century [3], especially in the middle latitude and arid areas [4]. As an important component of a terrestrial ecosystem [5], the dynamic changes of vegetation can reshape the global carbon and water cycle and energy flow [6]. The climate dynamics of vegetation change has become a hot topic in the field of ecology, geography, and climatology [4,7]. It is helpful to reveal the response of vegetation biophysics to climate change [1]. It is helpful to reveal the response of vegetation biophysics to climate change [1]. 4.0/).
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