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Global assessment of vegetation patterns along topographic gradients

Liang, Tianchen ; Tian, Feng ; Zou, Linqing ; Jin, Hongxiao LU ; Tagesson, Torbern LU ; Rumpf, Sabine B. ; He, Tao ; Liang, Shunlin and Fensholt, Rasmus (2024) In International Journal of Digital Earth 17(1). p.1-19
Abstract
The complex topography in mountainous regions, exemplified by factors like slope aspect, leads to noticeable variations in vegetation patterns, which are fundamental for understanding mountain ecosystems. However, a consistent global-scale quantification of topography's influence on vegetation patterns is still lacking. Here, we utilize two phenological metrics as proxies for vegetation-maximum vegetation greenness and seasonal greenness amplitude-computed from Sentinel-2 images, to quantify differences across three topographic factors: slope aspect, steepness, and elevation within each 0.15°×0.15° mountain grid. Our mapping reveals clear geographic patterns indicating that topography strongly influences vegetation in arid and polar... (More)
The complex topography in mountainous regions, exemplified by factors like slope aspect, leads to noticeable variations in vegetation patterns, which are fundamental for understanding mountain ecosystems. However, a consistent global-scale quantification of topography's influence on vegetation patterns is still lacking. Here, we utilize two phenological metrics as proxies for vegetation-maximum vegetation greenness and seasonal greenness amplitude-computed from Sentinel-2 images, to quantify differences across three topographic factors: slope aspect, steepness, and elevation within each 0.15°×0.15° mountain grid. Our mapping reveals clear geographic patterns indicating that topography strongly influences vegetation in arid and polar ecosystems, with an influence approximately 1.9 times higher than in temperate ecosystems. Topography is also important in humid regions, as demonstrated by diverse vegetation types growing on different slope aspects, steepness levels, and elevations. Additionally, the impacts of slope aspect, steepness, and elevation vary within the same region. In 25.9% of mountain grids, slope aspect causes the largest difference in vegetation patterns, while elevation and steepness account for 43.1% and 31%, respectively. Our study highlights the hotspot areas where topographic effects on vegetation patterns are most pronounced, enabling researchers to focus on these regions for better parameterization of Earth system models. (Less)
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author
; ; ; ; ; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Mountain ecosystems, vegetation pattern, Sentinel- 2, satellite remote sensing, topography
in
International Journal of Digital Earth
volume
17
issue
1
article number
2404232
pages
19 pages
publisher
Taylor & Francis
external identifiers
  • scopus:85204712530
ISSN
1753-8947
DOI
10.1080/17538947.2024.2404232
language
English
LU publication?
yes
id
5ae41a92-75bb-4ccc-ad68-8c6a61af55e8
date added to LUP
2024-10-15 09:29:22
date last changed
2025-04-04 14:41:00
@article{5ae41a92-75bb-4ccc-ad68-8c6a61af55e8,
  abstract     = {{The complex topography in mountainous regions, exemplified by factors like slope aspect, leads to noticeable variations in vegetation patterns, which are fundamental for understanding mountain ecosystems. However, a consistent global-scale quantification of topography's influence on vegetation patterns is still lacking. Here, we utilize two phenological metrics as proxies for vegetation-maximum vegetation greenness and seasonal greenness amplitude-computed from Sentinel-2 images, to quantify differences across three topographic factors: slope aspect, steepness, and elevation within each 0.15°×0.15° mountain grid. Our mapping reveals clear geographic patterns indicating that topography strongly influences vegetation in arid and polar ecosystems, with an influence approximately 1.9 times higher than in temperate ecosystems. Topography is also important in humid regions, as demonstrated by diverse vegetation types growing on different slope aspects, steepness levels, and elevations. Additionally, the impacts of slope aspect, steepness, and elevation vary within the same region. In 25.9% of mountain grids, slope aspect causes the largest difference in vegetation patterns, while elevation and steepness account for 43.1% and 31%, respectively. Our study highlights the hotspot areas where topographic effects on vegetation patterns are most pronounced, enabling researchers to focus on these regions for better parameterization of Earth system models.}},
  author       = {{Liang, Tianchen and Tian, Feng and Zou, Linqing and Jin, Hongxiao and Tagesson, Torbern and Rumpf, Sabine B. and He, Tao and Liang, Shunlin and Fensholt, Rasmus}},
  issn         = {{1753-8947}},
  keywords     = {{Mountain ecosystems; vegetation pattern; Sentinel- 2; satellite remote sensing; topography}},
  language     = {{eng}},
  month        = {{09}},
  number       = {{1}},
  pages        = {{1--19}},
  publisher    = {{Taylor & Francis}},
  series       = {{International Journal of Digital Earth}},
  title        = {{Global assessment of vegetation patterns along topographic gradients}},
  url          = {{http://dx.doi.org/10.1080/17538947.2024.2404232}},
  doi          = {{10.1080/17538947.2024.2404232}},
  volume       = {{17}},
  year         = {{2024}},
}