Global remote sensing reveals vegetation clustering as a physical footprint of shifting aridity trends in drylands
David Pinto-Ramos, Marcel Gabriel Clerc, Abdelkader Makhoute, Mustapha Tlidi
TLDR
This paper uses remote sensing to show that vegetation clustering reveals whether dryland ecosystems are degrading due to increasing aridity or recovering.
Key contributions
- Empirically validates vegetation pattern morphology as a physical footprint of aridity trends globally.
- Shows increasing aridity causes periodic vegetation arrays with defined wavelengths.
- Demonstrates decreasing aridity results in scale-free, disordered vegetation clustering.
- Offers a robust, non-destructive satellite indicator for dryland degradation or recovery.
Why it matters
This research provides a crucial, globally validated method to monitor dryland health. By using satellite data to identify distinct vegetation patterns, it offers a non-destructive way to diagnose whether ecosystems are degrading or recovering from aridity. This is vital for combating desertification and guiding conservation efforts.
Original Abstract
Due to climatic changes, excessive grazing, and deforestation, semi-arid and arid ecosystems are vulnerable to desertification and land degradation. As aridity increases, vegetation cover often self-organizes into spatial patterns before collapsing to bare soil. While recent theoretical work has established that spatially heterogeneous yet isotropic environments induce a smooth hysteresis loop -- yielding either periodic (hexagonal) patterns during degradation or disordered (clustered) patterns during recovery -- empirical validation of this physical footprint at a global scale has been lacking. Here, we present an extensive empirical validation using remote sensing across eight distinct global ecosystems, coupled with historical bio-climatic databases. We demonstrate that the spatial morphology of vegetation patches acts as a direct physical footprint of the ecosystem's historical aridity trend. Our results show that ecosystems experiencing increasing aridity display periodic arrays with a defined wavelength, whereas those recovering under decreasing aridity exhibit scale-free clustering. This framework provides a non-destructive, robust satellite-based indicator for diagnosing whether a dryland ecosystem is on a degradation or recovery pathway.
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