Abstract
The alpine timberline, an ecosystem ecotone, indicates climatic change and is tending to shift toward higher altitudes because of an increase in global warming. However, spatiotemporal variations of the alpine timberline are not consistent on a global scale. The abundant and highest alpine timberline, located on the Tibetan Plateau, is less subject to human activity and disturbance. Although many studies have investigated the alpine timberline on the Tibetan Plateau, large-scale monitoring of spatial-temporal dynamics and driving mechanisms of the alpine timberline remain uncertain and inaccurate. Hence, the Gongga Mountain on the southeastern Tibetan Plateau was chosen as the study area because of the most complete natural altitudinal zonation. We used the Otsu method on Google Earth Engine to extract the alpine timberline from 1987–2019 based on the normalized difference vegetation index (NDVI). Then, the alpine timberline spatiotemporal patterns and the effect of topography on alpine timberline distribution were explored. Four hillsides on the western Gongga Mountain were selected to examine the hillside differences and drivers of the alpine timberline based on principal component analysis (PCA) and multiple linear regression (MLR). The results indicated that the elevation range of alpine timberline was 3203–4889 m, and the vegetation coverage increased significantly (p < 0.01) near the alpine timberline ecotone on Gongga Mountain. Moreover, there was spatial heterogeneity in dynamics of alpine timberline, and some regions showed no regular trend in variations. The spatial pattern of the alpine timberline was generally high in the west, low in the east, and primarily distributed on 15–55° slopes. Besides, the drivers of the alpine timberline have the hillside differences, and the sunny and shady slopes possessed different driving factors. Thus, our results highlight the effects of topography and climate on the alpine timberline on different hillsides. These findings could provide a better approach to study the dynamics and formation of alpine timberlines.
Highlights
Structure, ecosystem processes, and functions of global vegetation communities and human livelihood have been seriously impacted adversely by climate change over the past 100 years [1]
Some studies showed that the population density of the Smith fir timberline in the southeastern Tibetan Plateau has significantly increased with climate warming since 200 years ago of another study that found a significant increase in the population density of Abies fabri near the alpine timberline in the Yajiageng area of Gongga Mountain over the past 100 years [32]
Some studies showed that the population density of the Smith fir timberline in the southeastern Tibetan Plateau has significantly increased with climate warming since 200 years ago [60]
Summary
Ecosystem processes, and functions of global vegetation communities and human livelihood have been seriously impacted adversely by climate change over the past 100 years [1]. Terrestrial ecosystems are undergoing long lasting, complex, and unpredictable changes as a consequence of variations in the global climate [2,3]. Vegetation, as a natural bond between soil, air and water, is crucial for global biodiversity conservation, ecosystem services and vision of human beings, it is highly sensitive to climate change [4]. Several cases worldwide have indicated that diverse vegetation patterns are greatly altered by global warming. In the ecosystem ecotone (such as alpine timberlines), the vegetation community structure, function and spatial pattern are especially sensitive to global change [10,11]
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