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Competitive exclusion principle

February 16, 2024

"Gause's law" redirects here. Not to be confused with Gauss's law.

In ecology, the competitive exclusion principle,[1] sometimes referred to as Gause's law,[2] is a proposition that two species which compete for the same limited resource cannot coexist at constant population values. When one species has even the slightest advantage over another, the one with the advantage will dominate in the long term. This leads either to the extinction of the weaker competitor or to an evolutionary or behavioral shift toward a different ecological niche. The principle has been paraphrased in the maxim "complete competitors can not coexist".[1]

1: A smaller (yellow) species of bird forages across the whole tree.
2: A larger (red) species competes for resources.
3: Red dominates in the middle for the more abundant resources. Yellow adapts to a new niche restricted to the top and bottom and avoiding competition.

History edit

The competitive exclusion principle is classically attributed to Georgy Gause,[3] although he actually never formulated it.[1] The principle is already present in Darwin's theory of natural selection.[2][4]

Throughout its history, the status of the principle has oscillated between a priori ('two species coexisting must have different niches') and experimental truth ('we find that species coexisting do have different niches').[2]

Experimental basis edit

 
Paramecium aurelia and Paramecium caudatum grow well individually, but when they compete for the same resources, P. aurelia outcompetes P. caudatum.

Based on field observations, Joseph Grinnell formulated the principle of competitive exclusion in 1904: "Two species of approximately the same food habits are not likely to remain long evenly balanced in numbers in the same region. One will crowd out the other".[5] Georgy Gause formulated the law of competitive exclusion based on laboratory competition experiments using two species of Paramecium, P. aurelia and P. caudatum. The conditions were to add fresh water every day and input a constant flow of food. Although P. caudatum initially dominated, P. aurelia recovered and subsequently drove P. caudatum extinct via exploitative resource competition. However, Gause was able to let the P. caudatum survive by differing the environmental parameters (food, water). Thus, Gause's law is valid only if the ecological factors are constant.

Gause also studied competition between two species of yeast, finding that Saccharomyces cerevisiae consistently outcompeted Schizosaccharomyces kefir[clarification needed] by producing a higher concentration of ethyl alcohol.[6]

Prediction edit

 
Cellular automaton model of interspecific competition for a single limited resource

Competitive exclusion is predicted by mathematical and theoretical models such as the Lotka–Volterra models of competition. However, for poorly understood reasons, competitive exclusion is rarely observed in natural ecosystems, and many biological communities appear to violate Gause's law. The best-known example is the so-called "paradox of the plankton".[7] All plankton species live on a very limited number of resources, primarily solar energy and minerals dissolved in the water. According to the competitive exclusion principle, only a small number of plankton species should be able to coexist on these resources. Nevertheless, large numbers of plankton species coexist within small regions of open sea.

Some communities that appear to uphold the competitive exclusion principle are MacArthur's warblers[8] and Darwin's finches,[9] though the latter still overlap ecologically very strongly, being only affected negatively by competition under extreme conditions.[10]

Paradoxical traits edit

A partial solution to the paradox lies in raising the dimensionality of the system. Spatial heterogeneity, trophic interactions, multiple resource competition, competition-colonization trade-offs, and lag may prevent exclusion (ignoring stochastic extinction over longer time-frames). However, such systems tend to be analytically intractable. In addition, many can, in theory, support an unlimited number of species. A new paradox is created: Most well-known models that allow for stable coexistence allow for unlimited number of species to coexist, yet, in nature, any community contains just a handful of species.

Redefinition edit

Recent studies addressing some of the assumptions made for the models predicting competitive exclusion have shown these assumptions need to be reconsidered. For example, a slight modification of the assumption of how growth and body size are related leads to a different conclusion, namely that, for a given ecosystem, a certain range of species may coexist while others become outcompeted.[11][12]

One of the primary ways niche-sharing species can coexist is the competition-colonization trade-off. In other words, species that are better competitors will be specialists, whereas species that are better colonizers are more likely to be generalists. Host-parasite models are effective ways of examining this relationship, using host transfer events. There seem to be two places where the ability to colonize differs in ecologically closely related species. In feather lice, Bush and Clayton[13] provided some verification of this by showing two closely related genera of lice are nearly equal in their ability to colonize new host pigeons once transferred. Harbison[14] continued this line of thought by investigating whether the two genera differed in their ability to transfer. This research focused primarily on determining how colonization occurs and why wing lice are better colonizers than body lice. Vertical transfer is the most common occurrence, between parent and offspring, and is much-studied and well understood. Horizontal transfer is difficult to measure, but in lice seems to occur via phoresis or the "hitchhiking" of one species on another. Harbison found that body lice are less adept at phoresis and excel competitively, whereas wing lice excel in colonization.

Support for a model of competition-colonization trade-off is also found in small mammals related to fire disturbances. In a project focused on the long-term impacts of the 1988 Yellowstone Fires Allen et al.[15] used stable isotopes and spatial mark-recapture data to show that Southern red-backed voles (Clethrionomys gapperi)), a specialist, are excluding deer mice (Peromyscus maniculatus), a generalist, from food resources in old-growth forests. However, after wildfire disturbance deer mice are more effective colonizers, and able to take advantage of the release from competitive pressure from voles. This dynamic of establishes a pattern of ecological succession in these ecosystems, with competitive exclusion from voles shaping the amount and quality of resources deer mice can access.

Phylogenetic context edit

An ecological community is the assembly of species which is maintained by ecological (Hutchinson, 1959;[16] Leibold, 1988[17]) and evolutionary process (Weiher and Keddy, 1995;[18] Chase et al., 2003). These two processes play an important role in shaping the existing community and will continue in the future (Tofts et al., 2000; Ackerly, 2003; Reich et al., 2003). In a local community, the potential members are filtered first by environmental factors such as temperature or availability of required resources and then secondly by its ability to co-exist with other resident species.

In an approach of understanding how two species fit together in a community or how the whole community fits together, The Origin of Species (Darwin, 1859) proposed that under homogeneous environmental condition struggle for existence is greater between closely related species than distantly related species. He also hypothesized that the functional traits may be conserved across phylogenies. Such strong phylogenetic similarities among closely related species are known as phylogenetic effects (Derrickson et al., 1988.[19])

With field study and mathematical models, ecologist have pieced together a connection between functional traits similarity between species and its effect on species co-existence. According to competitive-relatedness hypothesis (Cahil et al., 2008[20]) or phylogenetic limiting similarity hypothesis (Violle et al., 2011[21]) interspecific competition[22] is high among the species which have similar functional traits, and which compete for similar resources and habitats. Hence, it causes reduction in the number of closely related species and even distribution of it, known as phylogenetic overdispersion (Webb et al., 2002[23]). The reverse of phylogenetic overdispersion is phylogenetic clustering in which case species with conserved functional traits are expected to co-occur due to environmental filtering (Weiher et al., 1995; Webb, 2000). In the study performed by Webb et al., 2000, they showed that a small-plots of Borneo forest contained closely related trees together. This suggests that closely related species share features that are favored by the specific environmental factors that differ among plots causing phylogenetic clustering.

For both phylogenetic patterns (phylogenetic overdispersion and phylogenetic clustering), the baseline assumption is that phylogenetically related species are also ecologically similar (H. Burns et al., 2011[24]). There are no significant number of experiments answering to what degree the closely related species are also similar in niche. Due to that, both phylogenetic patterns are not easy to interpret. It's been shown that phylogenetic overdispersion may also result from convergence of distantly related species (Cavender-Bares et al. 2004;[25] Kraft et al. 2007[26]). In their study[citation needed], they have shown that traits are convergent rather than conserved. While, in another study[citation needed], it's been shown that phylogenetic clustering may also be due to historical or bio-geographical factors which prevents species from leaving their ancestral ranges. So, more phylogenetic experiments are required for understanding the strength of species interaction in community assembly.

Application to humans edit

Evidence showing that the competitive exclusion principle operates in human groups has been reviewed and integrated into regality theory to explain warlike and peaceful societies.[27] For example, hunter-gatherer groups surrounded by other hunter-gatherer groups in the same ecological niche will fight, at least occasionally, while hunter-gatherer groups surrounded by groups with a different means of subsistence can coexist peacefully.[27]

See also edit

References edit

  1. ^ a b c Garrett Hardin (1960). (PDF). Science. 131 (3409): 1292–1297. Bibcode:1960Sci...131.1292H. doi:10.1126/science.131.3409.1292. PMID 14399717. Archived from the original (PDF) on 2017-11-17. Retrieved 2016-11-24.
  2. ^ a b c Pocheville, Arnaud (2015). "The Ecological Niche: History and Recent Controversies". In Heams, Thomas; Huneman, Philippe; Lecointre, Guillaume; et al. (eds.). Handbook of Evolutionary Thinking in the Sciences. Dordrecht: Springer. pp. 547–586. ISBN 978-94-017-9014-7.
  3. ^ Gause, Georgii Frantsevich (1934). (1st ed.). Baltimore: Williams & Wilkins. Archived from the original on 2016-11-28. Retrieved 2016-11-24.
  4. ^ Darwin, Charles (1859). On the Origin of Species by Means of Natural Selection, or the Preservation of Favoured Races in the Struggle for Life (1st ed.). London: John Murray. ISBN 1-4353-9386-4.
  5. ^ Grinnell, J. (1904). "The Origin and Distribution of the Chestnut-Backed Chickadee". The Auk. American Ornithologists' Union. 21 (3): 364–382. doi:10.2307/4070199. JSTOR 4070199.
  6. ^ Gause, G.F. (1932). "Experimental studies on the struggle for existence: 1. Mixed population of two species of yeast" (PDF). Journal of Experimental Biology. 9: 389–402. doi:10.1242/jeb.9.4.389.
  7. ^ Hutchinson, George Evelyn (1961). "The paradox of the plankton". American Naturalist. 95 (882): 137–145. doi:10.1086/282171. S2CID 86353285.
  8. ^ MacArthur, R.H. (1958). "Population ecology of some warblers of northeastern coniferous forests". Ecology. 39 (4): 599–619. doi:10.2307/1931600. JSTOR 1931600. S2CID 45585254.
  9. ^ Lack, D.L. (1945). "The Galapagos finches (Geospizinae); a study in variation". Occasional Papers of the California Academy of Sciences. 21: 36–49.
  10. ^ De León, LF; Podos, J; Gardezi, T; Herrel, A; Hendry, AP (Jun 2014). "Darwin's finches and their diet niches: the sympatric coexistence of imperfect generalists". J Evol Biol. 27 (6): 1093–104. doi:10.1111/jeb.12383. PMID 24750315.
  11. ^ Rastetter, E.B.; Ågren, G.I. (2002). "Changes in individual allometry can lead to coexistence without niche separation". Ecosystems. 5: 789–801. doi:10.1007/s10021-002-0188-3. S2CID 30089349.
  12. ^ Moll, J.D.; Brown, J.S. (2008). "Competition and Coexistence with Multiple Life-History Stages". American Naturalist. 171 (6): 839–843. doi:10.1086/587517. PMID 18462131. S2CID 26151311.
  13. ^ Clayton, D.H.; Bush, S.E. (2006). "The role of body size in host specificity: Reciprocal transfer experiments with feather lice". Evolution. 60 (10): 2158–2167. doi:10.1111/j.0014-3820.2006.tb01853.x. PMID 17133872. S2CID 221734637.
  14. ^ Harbison, C.W. (2008). "Comparative transmission dynamics of competing parasite species". Ecology. 89 (11): 3186–3194. doi:10.1890/07-1745.1. PMID 31766819.
  15. ^ Allen, A.G.; Roehrs, Z.P.; Seville, R.S.; Lanier, H.C. (2022). "Competitive release during fire succession influences ecological turnover in a small mammal community". Ecology. 103 (8): 1–12. doi:10.1002/ecy.3733. PMC 9891167. PMID 35430726.
  16. ^ Hutchinson, G. E. (1959). "Homage to Santa Rosalia or Why Are There So Many Kinds of Animals?". The American Naturalist. 93 (870): 145–159. doi:10.1086/282070. ISSN 0003-0147. JSTOR 2458768. S2CID 26401739.
  17. ^ Leibold, MATHEW A. (1998-01-01). "Similarity and local co-existence of species in regional biotas". Evolutionary Ecology. 12 (1): 95–110. doi:10.1023/A:1006511124428. ISSN 1573-8477. S2CID 6678357.
  18. ^ Weiher, Evan; Keddy, Paul A. (1995). "The Assembly of Experimental Wetland Plant Communities". Oikos. 73 (3): 323–335. doi:10.2307/3545956. ISSN 0030-1299. JSTOR 3545956.
  19. ^ Derrickson, E. M.; Ricklefs, R. E. (1988). "Taxon-Dependent Diversification of Life-History Traits and the Perception of Phylogenetic Constraints". Functional Ecology. 2 (3): 417–423. doi:10.2307/2389415. ISSN 0269-8463. JSTOR 2389415.
  20. ^ Cahill, James F.; Kembel, Steven W.; Lamb, Eric G.; Keddy, Paul A. (2008-03-12). "Does phylogenetic relatedness influence the strength of competition among vascular plants?". Perspectives in Plant Ecology, Evolution and Systematics. 10 (1): 41–50. doi:10.1016/j.ppees.2007.10.001. ISSN 1433-8319.
  21. ^ Violle, Cyrille; Nemergut, Diana R.; Pu, Zhichao; Jiang, Lin (2011). "Phylogenetic limiting similarity and competitive exclusion". Ecology Letters. 14 (8): 782–787. doi:10.1111/j.1461-0248.2011.01644.x. ISSN 1461-0248. PMID 21672121.
  22. ^ Tarjuelo, R.; Morales, M. B.; Arroyo, B.; Mañosa, S.; Bota, G.; Casas, F.; Traba, J. (2017). "Intraspecific and interspecific competition induces density‐dependent habitat niche shifts in an endangered steppe bird". Ecology and Evolution. 7 (22): 9720–9730. doi:10.1002/ece3.3444. PMC 5696386. PMID 29188003.
  23. ^ Webb, Campbell O.; Ackerly, David D.; McPeek, Mark A.; Donoghue, Michael J. (2002). "Phylogenies and Community Ecology". Annual Review of Ecology and Systematics. 33 (1): 475–505. doi:10.1146/annurev.ecolsys.33.010802.150448. S2CID 535590.
  24. ^ Burns, Jean H.; Strauss, Sharon Y. (2011-03-29). "More closely related species are more ecologically similar in an experimental test". Proceedings of the National Academy of Sciences. 108 (13): 5302–5307. Bibcode:2011PNAS..108.5302B. doi:10.1073/pnas.1013003108. ISSN 0027-8424. PMC 3069184. PMID 21402914.
  25. ^ Cavender-Bares, J.; Ackerly, D. D.; Baum, D. A.; Bazzaz, F. A. (June 2004). "Phylogenetic overdispersion in Floridian oak communities". The American Naturalist. 163 (6): 823–843. doi:10.1086/386375. ISSN 1537-5323. PMID 15266381. S2CID 2959918.
  26. ^ Kraft, Nathan J. B.; Cornwell, William K.; Webb, Campbell O.; Ackerly, David D. (August 2007). "Trait evolution, community assembly, and the phylogenetic structure of ecological communities". The American Naturalist. 170 (2): 271–283. doi:10.1086/519400. ISSN 1537-5323. PMID 17874377. S2CID 7222026.
  27. ^ a b Fog, Agner (2017). Warlike and Peaceful Societies: The Interaction of Genes and Culture. Open Book Publishers. doi:10.11647/OBP.0128. ISBN 978-1-78374-403-9.

February 16, 2024
competitive, exclusion, principle, gause, redirects, here, confused, with, gauss, ecology, competitive, exclusion, principle, sometimes, referred, gause, proposition, that, species, which, compete, same, limited, resource, cannot, coexist, constant, population. Gause s law redirects here Not to be confused with Gauss s law In ecology the competitive exclusion principle 1 sometimes referred to as Gause s law 2 is a proposition that two species which compete for the same limited resource cannot coexist at constant population values When one species has even the slightest advantage over another the one with the advantage will dominate in the long term This leads either to the extinction of the weaker competitor or to an evolutionary or behavioral shift toward a different ecological niche The principle has been paraphrased in the maxim complete competitors can not coexist 1 1 A smaller yellow species of bird forages across the whole tree 2 A larger red species competes for resources 3 Red dominates in the middle for the more abundant resources Yellow adapts to a new niche restricted to the top and bottom and avoiding competition Contents 1 History 2 Experimental basis 3 Prediction 4 Paradoxical traits 5 Redefinition 6 Phylogenetic context 7 Application to humans 8 See also 9 ReferencesHistory editThe competitive exclusion principle is classically attributed to Georgy Gause 3 although he actually never formulated it 1 The principle is already present in Darwin s theory of natural selection 2 4 Throughout its history the status of the principle has oscillated between a priori two species coexisting must have different niches and experimental truth we find that species coexisting do have different niches 2 Experimental basis edit nbsp Paramecium aurelia and Paramecium caudatum grow well individually but when they compete for the same resources P aurelia outcompetes P caudatum Based on field observations Joseph Grinnell formulated the principle of competitive exclusion in 1904 Two species of approximately the same food habits are not likely to remain long evenly balanced in numbers in the same region One will crowd out the other 5 Georgy Gause formulated the law of competitive exclusion based on laboratory competition experiments using two species of Paramecium P aurelia and P caudatum The conditions were to add fresh water every day and input a constant flow of food Although P caudatum initially dominated P aurelia recovered and subsequently drove P caudatum extinct via exploitative resource competition However Gause was able to let the P caudatum survive by differing the environmental parameters food water Thus Gause s law is valid only if the ecological factors are constant Gause also studied competition between two species of yeast finding that Saccharomyces cerevisiae consistently outcompeted Schizosaccharomyces kefir clarification needed by producing a higher concentration of ethyl alcohol 6 Prediction edit nbsp Cellular automaton model of interspecific competition for a single limited resourceCompetitive exclusion is predicted by mathematical and theoretical models such as the Lotka Volterra models of competition However for poorly understood reasons competitive exclusion is rarely observed in natural ecosystems and many biological communities appear to violate Gause s law The best known example is the so called paradox of the plankton 7 All plankton species live on a very limited number of resources primarily solar energy and minerals dissolved in the water According to the competitive exclusion principle only a small number of plankton species should be able to coexist on these resources Nevertheless large numbers of plankton species coexist within small regions of open sea Some communities that appear to uphold the competitive exclusion principle are MacArthur s warblers 8 and Darwin s finches 9 though the latter still overlap ecologically very strongly being only affected negatively by competition under extreme conditions 10 Paradoxical traits editA partial solution to the paradox lies in raising the dimensionality of the system Spatial heterogeneity trophic interactions multiple resource competition competition colonization trade offs and lag may prevent exclusion ignoring stochastic extinction over longer time frames However such systems tend to be analytically intractable In addition many can in theory support an unlimited number of species A new paradox is created Most well known models that allow for stable coexistence allow for unlimited number of species to coexist yet in nature any community contains just a handful of species Redefinition editRecent studies addressing some of the assumptions made for the models predicting competitive exclusion have shown these assumptions need to be reconsidered For example a slight modification of the assumption of how growth and body size are related leads to a different conclusion namely that for a given ecosystem a certain range of species may coexist while others become outcompeted 11 12 One of the primary ways niche sharing species can coexist is the competition colonization trade off In other words species that are better competitors will be specialists whereas species that are better colonizers are more likely to be generalists Host parasite models are effective ways of examining this relationship using host transfer events There seem to be two places where the ability to colonize differs in ecologically closely related species In feather lice Bush and Clayton 13 provided some verification of this by showing two closely related genera of lice are nearly equal in their ability to colonize new host pigeons once transferred Harbison 14 continued this line of thought by investigating whether the two genera differed in their ability to transfer This research focused primarily on determining how colonization occurs and why wing lice are better colonizers than body lice Vertical transfer is the most common occurrence between parent and offspring and is much studied and well understood Horizontal transfer is difficult to measure but in lice seems to occur via phoresis or the hitchhiking of one species on another Harbison found that body lice are less adept at phoresis and excel competitively whereas wing lice excel in colonization Support for a model of competition colonization trade off is also found in small mammals related to fire disturbances In a project focused on the long term impacts of the 1988 Yellowstone Fires Allen et al 15 used stable isotopes and spatial mark recapture data to show that Southern red backed voles Clethrionomys gapperi a specialist are excluding deer mice Peromyscus maniculatus a generalist from food resources in old growth forests However after wildfire disturbance deer mice are more effective colonizers and able to take advantage of the release from competitive pressure from voles This dynamic of establishes a pattern of ecological succession in these ecosystems with competitive exclusion from voles shaping the amount and quality of resources deer mice can access Phylogenetic context editAn ecological community is the assembly of species which is maintained by ecological Hutchinson 1959 16 Leibold 1988 17 and evolutionary process Weiher and Keddy 1995 18 Chase et al 2003 These two processes play an important role in shaping the existing community and will continue in the future Tofts et al 2000 Ackerly 2003 Reich et al 2003 In a local community the potential members are filtered first by environmental factors such as temperature or availability of required resources and then secondly by its ability to co exist with other resident species In an approach of understanding how two species fit together in a community or how the whole community fits together The Origin of Species Darwin 1859 proposed that under homogeneous environmental condition struggle for existence is greater between closely related species than distantly related species He also hypothesized that the functional traits may be conserved across phylogenies Such strong phylogenetic similarities among closely related species are known as phylogenetic effects Derrickson et al 1988 19 With field study and mathematical models ecologist have pieced together a connection between functional traits similarity between species and its effect on species co existence According to competitive relatedness hypothesis Cahil et al 2008 20 or phylogenetic limiting similarity hypothesis Violle et al 2011 21 interspecific competition 22 is high among the species which have similar functional traits and which compete for similar resources and habitats Hence it causes reduction in the number of closely related species and even distribution of it known as phylogenetic overdispersion Webb et al 2002 23 The reverse of phylogenetic overdispersion is phylogenetic clustering in which case species with conserved functional traits are expected to co occur due to environmental filtering Weiher et al 1995 Webb 2000 In the study performed by Webb et al 2000 they showed that a small plots of Borneo forest contained closely related trees together This suggests that closely related species share features that are favored by the specific environmental factors that differ among plots causing phylogenetic clustering For both phylogenetic patterns phylogenetic overdispersion and phylogenetic clustering the baseline assumption is that phylogenetically related species are also ecologically similar H Burns et al 2011 24 There are no significant number of experiments answering to what degree the closely related species are also similar in niche Due to that both phylogenetic patterns are not easy to interpret It s been shown that phylogenetic overdispersion may also result from convergence of distantly related species Cavender Bares et al 2004 25 Kraft et al 2007 26 In their study citation needed they have shown that traits are convergent rather than conserved While in another study citation needed it s been shown that phylogenetic clustering may also be due to historical or bio geographical factors which prevents species from leaving their ancestral ranges So more phylogenetic experiments are required for understanding the strength of species interaction in community assembly Application to humans editEvidence showing that the competitive exclusion principle operates in human groups has been reviewed and integrated into regality theory to explain warlike and peaceful societies 27 For example hunter gatherer groups surrounded by other hunter gatherer groups in the same ecological niche will fight at least occasionally while hunter gatherer groups surrounded by groups with a different means of subsistence can coexist peacefully 27 See also editLimiting factor Limiting similarity Paradox of the planktonReferences edit a b c Garrett Hardin 1960 The competitive exclusion principle PDF Science 131 3409 1292 1297 Bibcode 1960Sci 131 1292H doi 10 1126 science 131 3409 1292 PMID 14399717 Archived from the original PDF on 2017 11 17 Retrieved 2016 11 24 a b c Pocheville Arnaud 2015 The Ecological Niche History and Recent Controversies In Heams Thomas Huneman Philippe Lecointre Guillaume et al eds Handbook of Evolutionary Thinking in the Sciences Dordrecht Springer pp 547 586 ISBN 978 94 017 9014 7 Gause Georgii Frantsevich 1934 The Struggle For Existence 1st ed Baltimore Williams amp Wilkins Archived from the original on 2016 11 28 Retrieved 2016 11 24 Darwin Charles 1859 On the Origin of Species by Means of Natural Selection or the Preservation of Favoured Races in the Struggle for Life 1st ed London John Murray ISBN 1 4353 9386 4 Grinnell J 1904 The Origin and Distribution of the Chestnut Backed Chickadee The Auk American Ornithologists Union 21 3 364 382 doi 10 2307 4070199 JSTOR 4070199 Gause G F 1932 Experimental studies on the struggle for existence 1 Mixed population of two species of yeast PDF Journal of Experimental Biology 9 389 402 doi 10 1242 jeb 9 4 389 Hutchinson George Evelyn 1961 The paradox of the plankton American Naturalist 95 882 137 145 doi 10 1086 282171 S2CID 86353285 MacArthur R H 1958 Population ecology of some warblers of northeastern coniferous forests Ecology 39 4 599 619 doi 10 2307 1931600 JSTOR 1931600 S2CID 45585254 Lack D L 1945 The Galapagos finches Geospizinae a study in variation Occasional Papers of the California Academy of Sciences 21 36 49 De Leon LF Podos J Gardezi T Herrel A Hendry AP Jun 2014 Darwin s finches and their diet niches the sympatric coexistence of imperfect generalists J Evol Biol 27 6 1093 104 doi 10 1111 jeb 12383 PMID 24750315 Rastetter E B Agren G I 2002 Changes in individual allometry can lead to coexistence without niche separation Ecosystems 5 789 801 doi 10 1007 s10021 002 0188 3 S2CID 30089349 Moll J D Brown J S 2008 Competition and Coexistence with Multiple Life History Stages American Naturalist 171 6 839 843 doi 10 1086 587517 PMID 18462131 S2CID 26151311 Clayton D H Bush S E 2006 The role of body size in host specificity Reciprocal transfer experiments with feather lice Evolution 60 10 2158 2167 doi 10 1111 j 0014 3820 2006 tb01853 x PMID 17133872 S2CID 221734637 Harbison C W 2008 Comparative transmission dynamics of competing parasite species Ecology 89 11 3186 3194 doi 10 1890 07 1745 1 PMID 31766819 Allen A G Roehrs Z P Seville R S Lanier H C 2022 Competitive release during fire succession influences ecological turnover in a small mammal community Ecology 103 8 1 12 doi 10 1002 ecy 3733 PMC 9891167 PMID 35430726 Hutchinson G E 1959 Homage to Santa Rosalia or Why Are There So Many Kinds of Animals The American Naturalist 93 870 145 159 doi 10 1086 282070 ISSN 0003 0147 JSTOR 2458768 S2CID 26401739 Leibold MATHEW A 1998 01 01 Similarity and local co existence of species in regional biotas Evolutionary Ecology 12 1 95 110 doi 10 1023 A 1006511124428 ISSN 1573 8477 S2CID 6678357 Weiher Evan Keddy Paul A 1995 The Assembly of Experimental Wetland Plant Communities Oikos 73 3 323 335 doi 10 2307 3545956 ISSN 0030 1299 JSTOR 3545956 Derrickson E M Ricklefs R E 1988 Taxon Dependent Diversification of Life History Traits and the Perception of Phylogenetic Constraints Functional Ecology 2 3 417 423 doi 10 2307 2389415 ISSN 0269 8463 JSTOR 2389415 Cahill James F Kembel Steven W Lamb Eric G Keddy Paul A 2008 03 12 Does phylogenetic relatedness influence the strength of competition among vascular plants Perspectives in Plant Ecology Evolution and Systematics 10 1 41 50 doi 10 1016 j ppees 2007 10 001 ISSN 1433 8319 Violle Cyrille Nemergut Diana R Pu Zhichao Jiang Lin 2011 Phylogenetic limiting similarity and competitive exclusion Ecology Letters 14 8 782 787 doi 10 1111 j 1461 0248 2011 01644 x ISSN 1461 0248 PMID 21672121 Tarjuelo R Morales M B Arroyo B Manosa S Bota G Casas F Traba J 2017 Intraspecific and interspecific competition induces density dependent habitat niche shifts in an endangered steppe bird Ecology and Evolution 7 22 9720 9730 doi 10 1002 ece3 3444 PMC 5696386 PMID 29188003 Webb Campbell O Ackerly David D McPeek Mark A Donoghue Michael J 2002 Phylogenies and Community Ecology Annual Review of Ecology and Systematics 33 1 475 505 doi 10 1146 annurev ecolsys 33 010802 150448 S2CID 535590 Burns Jean H Strauss Sharon Y 2011 03 29 More closely related species are more ecologically similar in an experimental test Proceedings of the National Academy of Sciences 108 13 5302 5307 Bibcode 2011PNAS 108 5302B doi 10 1073 pnas 1013003108 ISSN 0027 8424 PMC 3069184 PMID 21402914 Cavender Bares J Ackerly D D Baum D A Bazzaz F A June 2004 Phylogenetic overdispersion in Floridian oak communities The American Naturalist 163 6 823 843 doi 10 1086 386375 ISSN 1537 5323 PMID 15266381 S2CID 2959918 Kraft Nathan J B Cornwell William K Webb Campbell O Ackerly David D August 2007 Trait evolution community assembly and the phylogenetic structure of ecological communities The American Naturalist 170 2 271 283 doi 10 1086 519400 ISSN 1537 5323 PMID 17874377 S2CID 7222026 a b Fog Agner 2017 Warlike and Peaceful Societies The Interaction of Genes and Culture Open Book Publishers doi 10 11647 OBP 0128 ISBN 978 1 78374 403 9 Retrieved from https en wikipedia org w index php title Competitive exclusion principle amp oldid 1204268671, wikipedia, wiki, book, books, library,

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