Putting self‐organization to the test: labyrinthine patterns as optimal solution for persistence

Bertolini, Camilla; Cornelissen, Brenda; Koppel, Johan van de; Bouma, Tjeerd J.

doi:10.1111/oik.06373

Cited by 18 publications

(15 citation statements)

References 53 publications

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“…Therefore, while hydrology exerts clear control on the geometry of hummocks, hummocks may exert reciprocal control on hydrology by amplifying small hydrologic fluxes into large water level variations. Last, black ash hummocks provide unique microsite conditions that support increased vegetation growth and diver-sity (Diamond et al, 2019), aligning with observations in other wetland systems (Bledsoe and Shear, 2000;Peach and Zedler, 2006;Økland et al, 2008). Accordingly, recent wetland restoration efforts have begun to use microtopography as a strategy to promote seedling success and long-term project viability (Larkin et al, 2006;Bannister et al, 2013;Lieffers et al, 2017).…”

Section: Broader Implicationssupporting

confidence: 76%

“…Microtopography, or the small-scale structured variation (10 −1 -10 0 m) in ground surface height, is common to many ecosystems. Wetland microtopography is particularly well studied, and is found in freshwater marshes (van De Koppel and Crain, 2006), fens (Sullivan et al, 2008), peat bogs (Nungesser, 2003), forested swamps (Bledsoe and Shear, 2000), tidal freshwater swamps (Duberstein et al, 2013), and coastal marshes (Stribling et al, 2007). Wetland microtopography is common enough that researchers in disparate systems collectively refer to local high points as "hummocks" and local low points as "hollows".…”

Section: Introductionmentioning

confidence: 99%

“…In this way, vegetation may reinforce and maintain its own hummock microtopography (and thus preferred environmental conditions). Growing research across different ecosystems suggests that such reinforcing processes, or feedback loops, may be common between biota and their environment, and may result in characteristic, selforganized patch features (Rietkerk and Van de Koppel, 2008;Bertolini et al, 2019). By quantifying the structure and patterning of these features, we may therefore make processbased inferences about latent feedback mechanisms (Turner, 2005;Quintero and Cohen, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Pattern and structure of microtopography implies autogenic origins in forested wetlands

Diamond¹,

McLaughlin²,

Slesak³

et al. 2019

Hydrol. Earth Syst. Sci.

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Abstract. Wetland microtopography is a visually striking feature, but also critically influences biogeochemical processes at both the scale of its observation (10−2–102 m2) and at aggregate scales (102–104 m2). However, relatively little is known about how wetland microtopography develops or the factors influencing its structure and pattern. Growing research across different ecosystems suggests that reinforcing processes may be common between plants and their environment, resulting in self-organized patch features, like hummocks. Here, we used landscape ecology metrics and diagnostics to evaluate the plausibility of plant–environment feedback mechanisms in the maintenance of wetland microtopography. We used terrestrial laser scanning (TLS) to quantify the sizing and spatial distribution of hummocks in 10 black ash (Fraxinus nigra Marshall) wetlands in northern Minnesota, USA. We observed clear elevation bimodality in our wettest sites, indicating microsite divergence into two states: elevated hummocks and low elevation hollows. We coupled the TLS dataset to a 3-year water level record and soil-depth measurements, and showed that hummock height (mean = 0.31±0.06 m) variability is largely predicted by mean water level depth (R2=0.8 at the site scale, R2=0.12–0.56 at the hummock scale), with little influence of subsurface microtopography on surface microtopography. Hummocks at wetter sites exhibited regular spatial patterning (i.e., regular spacing of ca. 1.5 m, 25 %–30 % further apart than expected by chance) in contrast to the more random spatial arrangements of hummocks at drier sites. Hummock size distributions (perimeters, areas, and volumes) were lognormal, with a characteristic patch area of approximately 1 m2 across sites. Hummocks increase the effective soil surface area for redox gradients and exchange interfaces in black ash wetlands by up to 32 %, and influence surface water dynamics through modulation of specific yield by up to 30 %. Taken together, the data support the hypothesis that vegetation develops and maintains hummocks in response to anaerobic stresses from saturated soils, with a potential for a microtopographic signature of life.

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Section: Broader Implicationssupporting

confidence: 76%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Pattern and structure of microtopography implies autogenic origins in forested wetlands

Diamond¹,

McLaughlin²,

Slesak³

et al. 2019

Hydrol. Earth Syst. Sci.

View full text Add to dashboard Cite

show abstract

“…These substrata were chosen to represent a simple hard substratum where movement is maximised but attachment is limited (bare plastic tank) and a complex hard substratum where attachment is possible and often preferred (mixed cockles and mussels shell material, in pieces > 3cm, Capelle, Leuchter, Wit, Hartog, & Bouma, 2019, Bertolini, Geraldi, Montgomery, & Connor, 2017). Fifty mussels of either small (20.52 ± 0.61mm, mean ± SE ) or large (38.75 ± 0.54mm, mean ± SE) size classes were then added and spread evenly in one of the arenas (chosen at random) to obtain a density of 200 mussels/m 2 , representative of a natural lowmedium density (Bertolini et al, 2019), and were left for two hours to form byssal attachment. At the end of each two hours the total number of aggregated mussels was counted.…”

Section: Exp 1: Testing Cooperation Under Perceived Predation Risk Inmentioning

confidence: 99%

“…The aggregation into patches can be considered as a form of cooperation (Buss, 1981;Doebeli & Hauert, 2005), forming attachment with neighbouring mussels via production of byssal threads (Pearce & Labarbera, 2009). Attachment should protect mussels from dislodgement and predation (Bertness & Grosholz, 1985;Carrington, Moeser, Thompson, Coutts, & Craig, 2008;Hunt & Scheibling, 2001; de Koppel et al, 2008), and mussels ability to reorganise has consequences for system persistence (Bertolini, Cornelissen, Capelle, Van de Koppel, & Bouma, 2019) and habitat boundary formation at whole systems-scale which may ultimately determine species distribution in terms of its realised niche (Donahue, Desharnais, Robles, & Arriola, 2011). However, not all patterns may be created equal, and some patterns might appear similar while hiding differences in their strength.…”

Section: Introductionmentioning

confidence: 99%

Are all patterns created equal? Cooperation is more likely in spatially simple habitats

Bertolini

Hlebowicz²,

Schlichta³

et al. 2019

Marine Ecology

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A nucleation framework for transition between alternate states: short‐circuiting barriers to ecosystem recovery

Michaels

Eppinga

Bever

2020

Ecology

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The theory of alternate stable states provides an explanation for rapid ecosystem degradation, yielding important implications for ecosystem conservation and restoration. However, utilizing this theory to initiate transitions from degraded to desired ecosystem states remains a significant challenge. Applications of the alternative stable states framework may currently be impeded by a mismatch between local‐scale driving processes and landscape‐scale emergent system transitions. We show how nucleation theory provides an elegant bridge between local‐scale positive feedback mechanisms and landscape‐scale transitions between alternate stable ecosystem states. Geometrical principles can be used to derive a critical patch radius: a spatially explicit, local description of an unstable equilibrium point. This insight can be used to derive an optimal patch size that minimizes the cost of restoration, and to provide a framework to measure the resilience of desired ecosystem states to the synergistic effects of disturbance and environmental change.

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Putting self‐organization to the test: labyrinthine patterns as optimal solution for persistence

Cited by 18 publications

References 53 publications

Pattern and structure of microtopography implies autogenic origins in forested wetlands

Pattern and structure of microtopography implies autogenic origins in forested wetlands

Are all patterns created equal? Cooperation is more likely in spatially simple habitats

A nucleation framework for transition between alternate states: short‐circuiting barriers to ecosystem recovery

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