Partial Differential Equations in Ecology: Spatial Interactions and Population Dynamics

Holmes, Elizabeth E.; Lewis, Mark A.; Banks, John E.; Veit, Richard R.

doi:10.2307/1939378

Cited by 698 publications

(515 citation statements)

References 103 publications

(150 reference statements)

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“…We furthermore assume that movement of mussels is random and therefore adopt the classical diffusion approximation, where diffusion is a linear function of the Laplacian operator (Holmes et al 1994). Table 1 provides an over-DM view of the parameter values used, their units, and sources.…”

Section: ѩT Hmentioning

confidence: 99%

Scale‐Dependent Feedback and Regular Spatial Patterns in Young Mussel Beds

Koppel¹,

Rietkerk²,

Dankers³

et al. 2005

The American Naturalist

243

130

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In the past decade, theoretical ecologists have emphasized that local interactions between predators and prey may invoke emergent spatial patterning at larger spatial scales. However, empirical evidence for the occurrence of emergent spatial patterning is scarce, which questions the relevance of the proposed mechanisms to ecological theory. We report on regular spatial patterns in young mussel beds on soft sediments in the Wadden Sea. We propose that scale-dependent feedback, resulting from short-range facilitation by mutual protection from waves and currents and long-range competition for algae, induces spatial self-organization, thereby providing a possible explanation for the observed patterning. The emergent self-organization affects the functioning of mussel bed ecosystems by enhancing productivity and resilience against disturbance. Moreover, self-organization allows mussels to persist at algal concentrations that would not permit survival of mussels in a homogeneous bed. Our results emphasize the importance of self-organization in affecting the emergent properties of natural systems at larger spatial scales.

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Section: ѩT Hmentioning

confidence: 99%

Scale‐Dependent Feedback and Regular Spatial Patterns in Young Mussel Beds

Koppel¹,

Rietkerk²,

Dankers³

et al. 2005

The American Naturalist

243

130

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“…These models follow the general structure (Holmes et al 1994), as a crude approximation of lateral movement of both living material (e.g., through tillers) and wrack (falling from the plant or moved by the tides). Our model therefore likely underestimates the accumulation of wrack in the intertussock spaces.…”

Section: Model Formulationmentioning

confidence: 99%

Scale‐Dependent Inhibition Drives Regular Tussock Spacing in a Freshwater Marsh

Koppel¹,

Crain²

2006

The American Naturalist

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Online enhancements: videos, Matlab code.abstract: Regular spatial patterning is common in nature, and various mechanisms of self-organization have been proposed to explain regular patterning. We report on regular spatial patterning in Carex stricta in a freshwater wetland and investigate the applicability of theoretical models that explain regular patterning based on inhibition, facilitation, or interaction between the two. Spectral analysis of aerial photographs revealed that tussocks were regularly spaced at an average distance of 60 cm. Photosynthetically active radiation varied significantly with distance from the tussock and was lowest at intermediate distance from the tussock center (15-40 cm). Using transplants to assay growth conditions, we found that C. stricta grew well in all distance classes with and without natural C. stricta biomass, except at intermediate distances when buried in C. stricta wrack. Our experimental results reveal that C. stricta inhibits its growth in a scale-dependent manner: inhibition was found to peak at intermediate distance from the tussock. We compared three alternative models to examine potential mechanisms driving regularity and found that, similar to our experimental results, scale-dependent inhibition provides the best explanation for the observed regular tussock spacing. Our study underlines the importance of scale-dependent feedback in the formation of regular spatial patterning in ecosystems.

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“…Spatial structure in insect density has been observed at various scales for other pest species (Taylor, 1984;Liebhold et al, 1994) and may be caused by a variety of factors. Theoretical models (Durret & Levin, 1994;Holmes et al, 1994) show that processes such as dispersal and impact of natural enemies may lead to patchy distribution within a completely homogeneous habitat (i.e. where establishment is uniform).…”

Section: Discussionmentioning

confidence: 99%

Site condition and predation influence a bark beetle's success: a spatially realistic approach

Gilbert

Grégoire

2003

Agri and Forest Entomology

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1 Spatial pattern in abundance of Dendroctonus micans was studied in a 600-ha spruce stand in the Massif Central (LozeÁ re, France). The proportion of trees attacked was measured in 38 plots and these data were used to estimate spatial pattern of attack density in the stand and to identify a transect of decreasing attack density (80% to 30%) over less than 1000 m. 2 Spatial variation in attack density was analysed in relation to (i) data on site and stand characteristics (altitude, slope, tree density, tree average height, yield class and average age) collected from 63 points in the stand and (ii) the releases of the predator Rhizophagus grandis (localization and number of beetles released). 3 The proportion of attacked trees was analysed using geostatistics and showed a strong spatial structure reflecting the spatial scale of interaction of D. micans with its environment. The spatial structure was modelled in order to estimate the spatial distribution of attack density at unsampled locations. 4 A linear model relating interpolated attack density to the number of predators released 6±10 years before the survey in a 300-m radius and to the average slope over a 250-m radius explained 67% of the observed variability. Spatial autocorrelation was taken into account in a spatial regression model.

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Partial Differential Equations in Ecology: Spatial Interactions and Population Dynamics

Cited by 698 publications

References 103 publications

Scale‐Dependent Feedback and Regular Spatial Patterns in Young Mussel Beds

Scale‐Dependent Feedback and Regular Spatial Patterns in Young Mussel Beds

Scale‐Dependent Inhibition Drives Regular Tussock Spacing in a Freshwater Marsh

Site condition and predation influence a bark beetle's success: a spatially realistic approach

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