Contrasting Global Patterns of Spatially Periodic Fairy Circles and Regular Insect Nests in Drylands

Getzin, Stephan; Yizhaq, Hezi; Cramer, Michael D.; Tschinkel, Wälter R.

doi:10.1029/2019jg005393

Cited by 23 publications

(48 citation statements)

References 84 publications

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“…13 ), this measure changes weakly with competitive strength, suggesting that statistical approaches to measuring competition are limited. Instead, an integrated framework considering deviations from predicted scaling in demographics as well as spatial patterning may better specify the range of competitive forces acting across environments ( 4 , 18 , 60 , 82 , 83 ).…”

Section: Discussionmentioning

confidence: 99%

Growth, death, and resource competition in sessile organisms

Lee

Kempes

West

2021

Proc. Natl. Acad. Sci. U.S.A.

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Population-level scaling in ecological systems arises from individual growth and death with competitive constraints. We build on a minimal dynamical model of metabolic growth where the tension between individual growth and mortality determines population size distribution. We then separately include resource competition based on shared capture area. By varying rates of growth, death, and competitive attrition, we connect regular and random spatial patterns across sessile organisms from forests to ants, termites, and fairy circles. Then, we consider transient temporal dynamics in the context of asymmetric competition, such as canopy shading or large colony dominance, whose effects primarily weaken the smaller of two competitors. When such competition couples slow timescales of growth to fast competitive death, it generates population shocks and demographic oscillations similar to those observed in forest data. Our minimal quantitative theory unifies spatiotemporal patterns across sessile organisms through local competition mediated by the laws of metabolic growth, which in turn, are the result of long-term evolutionary dynamics.

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Section: Discussionmentioning

confidence: 99%

Growth, death, and resource competition in sessile organisms

Lee

Kempes

West

2021

Proc. Natl. Acad. Sci. U.S.A.

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“…The FCs are distributed in a spatially periodic pattern and, as predicted by pattern‐formation theory, form a grid‐like hexagonal array (Getzin, Yizhaq, Cramer, et al, 2019). Our empirical results thus support the theoretical model assumptions based on the reaction‐diffusion principle and scale‐dependent feedbacks where the hardened FC gaps function as an important additional source of water for the surrounding vegetation matrix (Getzin et al., 2016; Meron, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…This signature is characterized by each fairy circle having on average six nearest neighbours that are located at approximately the same distance from the focal circle, leading to a hexagonal grid. The fairy circles are thus spatially periodic and constitute probably the most regularly distributed vegetation gaps that are currently known from arid environments (Getzin, Yizhaq, Cramer, & Tschinkel, 2019; Getzin, Yizhaq, Munoz‐Rojas, Wiegand, & Erickson, 2019). It is obvious that such exceptionally ordered patterns can only result from strong interactive processes, because in the absence of interaction, the probability of creating order in a noisy environment is very unlikely (Saha & Galic, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Fairy circles (FCs) are subject to an ongoing controversy about their origin (Sahagian, 2017). More recent theories have focused on vegetation self‐organization and argued that FCs are an emergent vegetation phenomenon that reflects a population‐level response to aridity stress where ecohydrological biomass‐water feedbacks lead to strictly geometric patterns (Cramer & Barger, 2013; Cramer, Barger, & Tschinkel, 2017; Getzin et al., 2015a,b; 2016; Getzin, Yizhaq, Cramer, et al, 2019; Ravi, Wang, Kaseke, Buynevich, & Marais, 2017; Zelnik, Meron, & Bel, 2015). The periodically ordered pattern is thus an expression that there is not enough water to sustain uniform vegetation coverage at the landscape scale and the distinct, so‐called ‘wavelength’ of the gap pattern reflects the spatial scale at which water is most limiting to the plants (Meron, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…This successful matching, however, is not a verification that the modelled processes and mechanisms of plant self‐organization are indeed right and happening in the real world to cause the observed patterns (Borgogno et al., 2009). Within a framework of pattern‐process inference, these coarse‐graining methods are mainly useful to identify unlikely processes for the cause of the pattern and to narrow down the most plausible working hypotheses (Getzin, Yizhaq, Cramer, et al, 2019; McIntire & Fajardo, 2009; Schurr, Bossdorf, Milton, & Schumacher, 2004). Consequently, if the extensive achievements of the mathematical process‐based models are to find greater acceptance in ecology, then it is necessary not only to reconstruct the higher‐level structures but also to demonstrate true evidence of the validity of the modelled lower‐level processes assumed a priori.…”

Section: Introductionmentioning

confidence: 99%

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Bridging ecology and physics: Australian fairy circles regenerate following model assumptions on ecohydrological feedbacks

et al. 2020

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High-resolution images and drone-based LiDAR reveal striking patterns of vegetation gaps in a wooded spinifex grassland of Western Australia

et al. 2021

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Context Vegetation 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. Objectives To 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. Methods We 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. Results The 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. Conclusions The 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.

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Contrasting Global Patterns of Spatially Periodic Fairy Circles and Regular Insect Nests in Drylands

Cited by 23 publications

References 84 publications

Growth, death, and resource competition in sessile organisms

Growth, death, and resource competition in sessile organisms

Bridging ecology and physics: Australian fairy circles regenerate following model assumptions on ecohydrological feedbacks

High-resolution images and drone-based LiDAR reveal striking patterns of vegetation gaps in a wooded spinifex grassland of Western Australia

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