Ecological trap

Last updated December 29, 2023

Ecological traps are scenarios in which rapid environmental change leads organisms to prefer to settle in poor-quality habitats. The concept stems from the idea that organisms that are actively selecting habitat must rely on environmental cues to help them identify high-quality habitat. If either the habitat quality or the cue changes so that one does not reliably indicate the other, organisms may be lured into poor-quality habitat.

Overview

Ecological traps are thought to occur when the attractiveness of a habitat increases disproportionately in relation to its value for survival and reproduction. The result is preference of falsely attractive habitat and a general avoidance of high-quality but less-attractive habitats. For example, Indigo buntings typically nest in shrubby habitat or broken forest transitions between closed canopy forest and open field. Human activity can create 'sharper', more abrupt forest edges and buntings prefer to nest along these edges. However, these artificial sharp forest edges also concentrate the movement of predators which predate their nests. In this way, Buntings prefer to nest in highly altered habitats where their nest success is lowest.^[1]

While the demographic consequences of this type of maladaptive habitat selection behavior have been explored in the context of the sources and sinks, ecological traps are an inherently behavioral phenomenon of individuals.^[2] Despite being a behavioural mechanism, ecological traps can have far-reaching population consequences for species with large dispersal capabilities, such as the grizzly bear (Ursus arctos).^[3] The ecological trap concept was introduced in 1972 by Dwernychuk and Boag^[4] and the many studies that followed suggested that this trap phenomenon may be widespread because of anthropogenic habitat change.^[2]^[5]^[6]

As a corollary, novel environments may represent fitness opportunities that are unrecognized by native species if high-quality habitats lack the appropriate cues to encourage settlement; these are known as perceptual traps.^[7] Theoretical^[8] and empirical studies^[1]^[4] have shown that errors made in judging habitat quality can lead to population declines or extinction. Such mismatches are not limited to habitat selection, but may occur in any behavioral context (e.g. predator avoidance, mate selection, navigation, foraging site selection, etc.). Ecological traps are thus a subset of the broader phenomena of evolutionary traps.^[5]

As ecological trap theory developed, researchers have recognized that traps may operate on a variety of spatial and temporal scales which might also hinder their detection. For example, because a bird must select habitat on several scales (a habitat patch, an individual territory within that patch, as well as a nest site within the territory), traps may operate on any one of these scales.^[9] Similarly, traps may operate on a temporal scale so that an altered environment may appear to cause a trap in one stage of an organism's life, yet have positive effects on later life stages.^[5] As a result, there has been a great deal of uncertainty as to how common traps may be, despite widespread acceptance as a theoretical possibility.^[2] However, given the accelerated rate of ecological change driven by human land-use change, global warming, exotic species invasions, and changes in ecological communities resulting from species loss, ecological traps may be an increasing and highly underappreciated threat to biodiversity.

A 2006 review of the literature on ecological traps provides guidelines for demonstrating the existence of an ecological trap.^[2] A study must show a preference for one habitat over another (or equal preference) and that individuals selecting the preferred habitat (or equally preferred habitat) have lower fitness (i.e., experience lower survival or reproductive success). Since the publication of that paper which found only a few well-documented examples of ecological traps, interest in ecological and evolutionary traps has grown very rapidly and new empirical examples are being published at an accelerating rate. There are now roughly 30 examples of ecological traps affecting a broad diversity of taxa including birds, mammals, arthropods, fish and reptiles.

Because ecological and evolutionary traps are still very poorly understood phenomena, many questions about their proximate and ultimate causes as well as their ecological consequences remain unanswered. Are traps simply an inevitable consequence of the inability of evolution to anticipate novelty or react quickly to rapid environmental change? How common are traps? Do ecological traps necessarily lead to population declines or extinctions or is it possible that they may persist indefinitely? Under what ecological and evolutionary conditions should this occur? Are organisms with certain characteristics predisposed to being "trapped"? Is rapid environmental change necessary to trigger traps? Can global warming, pollution or exotic invasive species create traps? Embracing genetic and phylogenetic approaches may provide more robust answers to the above questions as well as providing deeper insight into the proximate and ultimate basis for maladaptation in general^{[ citation needed ]}. Because ecological and evolutionary traps are predicted to add in concert with other sources of population decline, traps are an important research priority for conservation scientists. Given the rapid current rate of global environmental change, traps may be far more common than it is realized and it will be important to examine the proximate and ultimate causes of traps if management is to prevent or eliminate traps in the future.

Polarized light pollution

Polarized light pollution is perhaps the most compelling and well-documented cue triggering ecological traps.^[10] Orientation to polarized sources of light is the most important mechanism that guides at least 300 species of dragonflies, mayflies, caddisflies, tabanid flies, diving beetles, water bugs, and other aquatic insects in their search for the water bodies they require for suitable feeding/breeding habitat and oviposition sites (Schwind 1991; Horváth and Kriska 2008). Because of their strong linear polarization signature, artificial polarizing surfaces (e.g., asphalt, gravestones, cars, plastic sheeting, oil pools, windows) are commonly mistaken for bodies of water (Horváth and Zeil 1996; Kriska et al. 1998, 2006a, 2007, 2008; Horváth et al. 2007, 2008). Light reflected by these surfaces is often more highly polarized than that of light reflected by water, and artificial polarizers can be even more attractive to polarotactic aquatic insects than a water body (Horváth and Zeil 1996; Horváth et al. 1998; Kriska et al. 1998) and appear as exaggerated water surfaces acting as supernormal optical stimuli. Consequently, dragonflies, mayflies, caddisflies, and other water-seeking species actually prefer to mate, settle, swarm, and oviposit upon these surfaces than on available water bodies.

Notes

1 2 Weldon, A.J.; Haddad, N.M. (2005). "The effects of patch shape on Indigo Buntings: Evidence for an ecological trap". Ecology . 86 (6): 1422–1431. Bibcode:2005Ecol...86.1422W. doi:10.1890/04-0913.
1 2 3 4 Robertson, B.A.; Hutto, R.L. (2006). "A framework for understanding ecological traps and an evaluation of existing evidence". Ecology . 87 (5): 1075–1085. doi:10.1890/0012-9658(2006)87[1075:AFFUET]2.0.CO;2. ISSN 0012-9658. PMID 16761584. S2CID 266029513.
↑ Lamb, C.T..; Mowat, G.; McLellan, B.N.; Nielsen, S.E.; Boutin, S. (2017). "Forbidden fruit: human settlement and abundant fruit create an ecological trap for an apex omnivore". Journal of Animal Ecology . 86 (1): 55–65. Bibcode:2017JAnEc..86...55L. doi: 10.1111/1365-2656.12589 . PMID 27677529.
1 2 Dwernychuk, L.W.; Boag, D.A. (1972). "Ducks nesting in association with gulls-an ecological trap?". Canadian Journal of Zoology . 50 (5): 559–563. doi:10.1139/z72-076.
1 2 3 Schlaepfer, M.A.; Runge, M.C.; Sherman, P.W. (2002). "Ecological and evolutionary traps". Trends in Ecology and Evolution . 17 (10): 474–480. doi:10.1016/S0169-5347(02)02580-6.
↑ Battin, J. (2004). "When good animals love bad habitats: Ecological traps and the conservation of animal populations". Conservation Biology . 18 (6): 1482–1491. Bibcode:2004ConBi..18.1482B. doi:10.1111/j.1523-1739.2004.00417.x. S2CID 2383356.
↑ Patten, M.A.; Kelly, J.F. (2010). "Habitat selection and the perceptual trap". Ecological Applications. 20 (8): 2148–56. Bibcode:2010EcoAp..20.2148P. doi:10.1890/09-2370.1. PMID 21265448.
↑ Delibes, M.; Gaona, P.; Ferreras, P. (2001). "Effects of an attractive sink leading into maladaptive habitat selection". American Naturalist . 158 (3): 277–285. doi:10.1086/321319. hdl: 10261/50227 . PMID 18707324. S2CID 1345605.
↑ Misenhelter, M.D.; Rotenberry, J.T. (2000). "Choices and consequences of habitat occupancy and nest site selection in sage sparrows". Ecology . 81 (10): 2892–2901. doi:10.1890/0012-9658(2000)081[2892:CACOHO]2.0.CO;2. ISSN 0012-9658.
↑ Horvath et al., in press as of Jan, 2013

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References

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v t e Ecology: Modelling ecosystems: Trophic components
General	Abiotic component Abiotic stress Behaviour Biogeochemical cycle Biomass Biotic component Biotic stress Carrying capacity Competition Ecosystem Ecosystem ecology Ecosystem model Keystone species List of feeding behaviours Metabolic theory of ecology Productivity Resource Restoration
Producers	Autotrophs Chemosynthesis Chemotrophs Foundation species Kinetotrophs Mixotrophs Myco-heterotrophy Mycotroph Organotrophs Photoheterotrophs Photosynthesis Photosynthetic efficiency Phototrophs Primary nutritional groups Primary production
Consumers	Apex predator Bacterivore Carnivores Chemoorganotroph Foraging Generalist and specialist species Intraguild predation Herbivores Heterotroph Heterotrophic nutrition Insectivore Mesopredators Mesopredator release hypothesis Omnivores Optimal foraging theory Planktivore Predation Prey switching
Decomposers	Chemoorganoheterotrophy Decomposition Detritivores Detritus
Microorganisms	Archaea Bacteriophage Lithoautotroph Lithotrophy Marine Microbial cooperation Microbial ecology Microbial food web Microbial intelligence Microbial loop Microbial mat Microbial metabolism Phage ecology
Food webs	Biomagnification Ecological efficiency Ecological pyramid Energy flow Food chain Trophic level
Example webs	Lakes Rivers Soil Tritrophic interactions in plant defense Marine food webs cold seeps hydrothermal vents intertidal kelp forests North Pacific Gyre San Francisco Estuary tide pool
Processes	Ascendency Bioaccumulation Cascade effect Climax community Competitive exclusion principle Consumer–resource interactions Copiotrophs Dominance Ecological network Ecological succession Energy quality Energy systems language f-ratio Feed conversion ratio Feeding frenzy Mesotrophic soil Nutrient cycle Oligotroph Paradox of the plankton Trophic cascade Trophic mutualism Trophic state index
Defense, counter	Animal coloration Anti-predator adaptations Camouflage Deimatic behaviour Herbivore adaptations to plant defense Mimicry Plant defense against herbivory Predator avoidance in schooling fish

v t e Ecology: Modelling ecosystems: Other components
Population ecology	Abundance Allee effect Depensation Ecological yield Effective population size Intraspecific competition Logistic function Malthusian growth model Maximum sustainable yield Overpopulation Overexploitation Population cycle Population dynamics Population modeling Population size Predator–prey (Lotka–Volterra) equations Recruitment Small population size Stability Resilience Resistance
Species	Biodiversity Density-dependent inhibition Ecological effects of biodiversity Ecological extinction Endemic species Flagship species Gradient analysis Indicator species Introduced species Invasive species Latitudinal gradients in species diversity Minimum viable population Neutral theory Occupancy–abundance relationship Population viability analysis Priority effect Rapoport's rule Relative abundance distribution Relative species abundance Species diversity Species homogeneity Species richness Species distribution Species–area curve Umbrella species
Species interaction	Antibiosis Biological interaction Commensalism Community ecology Ecological facilitation Interspecific competition Mutualism Parasitism Storage effect Symbiosis
Spatial ecology	Biogeography Cross-boundary subsidy Ecocline Ecotone Ecotype Disturbance Edge effects Foster's rule Habitat fragmentation Ideal free distribution Intermediate disturbance hypothesis Insular biogeography Land change modeling Landscape ecology Landscape epidemiology Landscape limnology Metapopulation Patch dynamics r/K selection theory Resource selection function Source–sink dynamics
Niche	Ecological niche Ecological trap Ecosystem engineer Environmental niche modelling Guild Habitat marine habitats Limiting similarity Niche apportionment models Niche construction Niche differentiation Ontogenetic niche shift
Other networks	Assembly rules Bateman's principle Bioluminescence Ecological collapse Ecological debt Ecological deficit Ecological energetics Ecological indicator Ecological threshold Ecosystem diversity Emergence Extinction debt Kleiber's law Liebig's law of the minimum Marginal value theorem Thorson's rule Xerosere
Other	Allometry Alternative stable state Balance of nature Biological data visualization Ecological economics Ecological footprint Ecological forecasting Ecological humanities Ecological stoichiometry Ecopath Ecosystem based fisheries Endolith Evolutionary ecology Functional ecology Industrial ecology Macroecology Microecosystem Natural environment Regime shift Sexecology Systems ecology Urban ecology Theoretical ecology
Outline of ecology

Ecological trap

Contents

Overview

Polarized light pollution

See also

Notes

Related Research Articles

References

Further reading