Abstract
ContextVegetation patterns in hummock grasslands of Australia’s arid interior can be very complex. Additionally, the grasslands are interspersed with variable amounts of trees and shrubs.ObjectivesTo better understand the spatial arrangement of this vegetation structure, and in particular the unvegetated bare-soil gaps, we analyzed the scale-dependent patterns of gaps, trees, and shrubs.MethodsWe focused on two size categories of grassland gaps, large gaps ≥ 4 m2 known as fairy circles (FCs) and small gaps 1 to < 4 m2, and on trees and shrubs. We mapped four 200 m × 200 m study plots located east of the town of Newman in Western Australia, using drone-based aerial images and LiDAR. The RGB images were converted into binary images and the gaps and woody plants were automatically segmented. The spatial patterns of the four vegetation components were analyzed, as well as the shape properties of the vegetation gaps.ResultsThe most striking result was that small gaps appeared consistently at about 5 m distance away from the FCs, which are known as the most water-depleted locations in the grassland. The FCs were also rounder than the small gaps and this symmetry underlines their function as an extra source of water for the surrounding matrix vegetation. Trees and shrubs had spatial patterns that were unrelated to FCs, which likely results from their water uptake in deeper sub-soil layers.ConclusionsThe consistent distance of small gaps to FCs is further support that the Australian fairy circles are a self-organized vegetation pattern that results from ecohydrological feedbacks.
Highlights
IntroductionThe most famous grassland gaps are the so-called fairy circles
Grassland gaps in arid ecosystems are common throughout the world
Trees and shrubs had spatial patterns that were unrelated to fairy circles (FCs), which likely results from their water uptake in deeper sub-soil layers
Summary
The most famous grassland gaps are the so-called fairy circles These fairy circles (FCs) are relatively large and round vegetation gaps that occur in a small area of Western Australia and along the Namib Desert in southwestern Africa. One important aspect that characterizes the FCs is their unique ability to form so-called ‘‘spatially periodic’’ patterns, where the six nearest neighbors around any focal FC have approximately the same distances to the focal FC. Such FC distributions are a special form of a regular pattern with an extraordinary degree of overdispersion, and they appear so striking to the observer because of their strictly geometric spatial ordering (Getzin et al 2019a)
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