Abstract
Spatiotemporal patterns of global forest net primary productivity (NPP) are pivotal for us to understand the interaction between the climate and the terrestrial carbon cycle. In this study, we use Google Earth Engine (GEE), which is a powerful cloud platform, to study the dynamics of the global forest NPP with remote sensing and climate datasets. In contrast with traditional analyses that divide forest areas according to geographical location or climate types to retrieve general conclusions, we categorize forest regions based on their NPP levels. Nine categories of forests are obtained with the self-organizing map (SOM) method, and eight relative factors are considered in the analysis. We found that although forests can achieve higher NPP with taller, denser and more broad-leaved trees, the influence of the climate is stronger on the NPP; for the high-NPP categories, precipitation shows a weak or negative correlation with vegetation greenness, while lacking water may correspond to decrease in productivity for low-NPP categories. The low-NPP categories responded mainly to the La Niña event with an increase in the NPP, while the NPP of the high-NPP categories increased at the onset of the El Niño event and decreased soon afterwards when the warm phase of the El Niño-Southern Oscillation (ENSO) wore off. The influence of the ENSO changes correspondingly with different NPP levels, which infers that the pattern of climate oscillation and forest growth conditions have some degree of synchronization. These findings may facilitate the understanding of global forest NPP variation from a different perspective.
Highlights
Forests play an important role in the global carbon cycle, and the net primary productivity (NPP) of forests is a vital indicator that relates to its ecological characteristics and regional climate and highly depends on their ability to adapt to changes in the surroundings [1]
We have developed a method to analyze the spatiotemporal patterns of global forest NPP and its relationship to diverse impact factors during 2004–2013 from a NPP-category perspective using the big data platform Google Earth Engine (GEE)
The forest areas are categorized with the self-organizing map (SOM) algorithm based on the NPP time series in 10 years to consider their carbon absorption behaviors
Summary
Forests play an important role in the global carbon cycle, and the net primary productivity (NPP) of forests is a vital indicator that relates to its ecological characteristics and regional climate and highly depends on their ability to adapt to changes in the surroundings [1]. Previous studies showed that high temperature and water deficit constrain the accumulation of forest NPP [2,3,4,5], and radiation-limited vegetation accounts for approximately 27% of the earth’s vegetation surface [6]. Forest traits and cover densities have strong effects on forest NPP [7,8,9,10].
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