Abstract
Competition theory has had a major influence on ecological thought for at least the last 60 years, with a special focus during the late 1950s through the 1970s (e.g. Hutchinson 1957, MacArthur and Levins 1964; Schoener 1974a). This led to the extensive development of niche theory (e.g. Hutchinson 1957; Pianka 1974; Whittaker and Levin 1975), linking competition pressures with observed resource use by competitors, both inter- and intraspecific (see Colwell and Fuentes 1975; Giller 1984 for reviews). As a result, terms such as niche release, niche shift and niche expansion are used to describe a species’ response to its competitor’s presence or absence. Dissimilarity between competing species in their foraging behaviour or habitat use is sometimes called ‘niche differentiation’. Previous theoretical (e.g. May 1973) and experimental (e.g. Park 1962) studies on interspecific competition concluded that niche differentiation is necessary for competitive coexistence in interactive communities (i.e., communities that are mainly influenced by density-dependent processes such as competition and predation). As a result, the way in which ecologically-related species partition resources to avoid competitive exclusion has attracted the attention of ecologists for many years (e.g. MacArthur 1958; Schoener 1974a, b, 1986a).
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References
Abramsky Z (1988) The role of habitat and productivity in structuring desert rodent communities. Oikos 52:107–114
Abramsky Z, Pinshow B (1989) Changes in foraging efforts in two gerbil species correlate with habitat type and intra-and interspecific activities. Oikos 56:43–53
Abramsky Z, Rosenzweig ML, Pinshow B, Brown JS, Kotler BP, Mitchell WA (1990) Habitat selection: an experimental field test with two gerbil species. Ecology 71:2358–2369
Abramsky Z, Rosenzweig ML, Pinshow B (1991) The shape of a gerbil isocline measured using principles of optimal selection. Ecology 72:329–340
Abramsky Z, Rosenzweig ML, Subach A (1992) The shape of a gerbil isocline: an experimental field study. Oikos 63:193–199
Abramsky Z, Ovadia O, Rosenzweig ML (1994) The shape of a Gerbillus pyramidum (Rodentia: Gerbillinae) isocline: an experimental field study. Oikos 69:318–326
Bar Y, Abramsky Z, Gutterman Y (1984) Diet of Gerbilline rodents in the Israeli desert. J Arid Environ 7:371–376
Bowers MA, Thompson DB, Brown JH (1987) The spatial organization of a desert rodent community: food addition and species removal. Oecologia 72:77–82
Brown JH (1975) Geographical ecology of desert rodents. In: Cody ML, Diamond JM (eds) Ecology and evolution of communities. Harvard University Press, Cambridge, pp 315–341
Brown JH, Harney BA (1993) Population and community ecology of heteromyid rodents in temperate habitats. In: Genoways HH, Brown JH (eds) Biology of the heteromyidae. Am Soc Mammal Spec Publ 10, Lawrence, pp 618–651
Brown JH, Reichman OJ, Davidson DW (1979) Granivory in desert ecosystems. Annu Rev Ecol Syst 10:201–227
Brown JH, Davidson DW, Munger JC, Inouye RS (1986) Experimental community ecology: the desert granivory system. In: Diamond JM, Case TJ (eds) Community ecology. Harper and Row, New York, pp 41–61
Brown JS (1986) Coexistence on a resource whose abundance varies: a test with desert rodents. PhD thesis, University of Arizona, Tucson
Brown JS (1988) Patch use as an indicator of habitat preference, predation risk, and competition. Behav Ecol Sociobiol 22:37–47
Brown JS (1989a) Coexistence on a seasonal resource. Am Nat 133:168–182
Brown JS (1989b) Desert rodent community structure: a test of four mechanisms of coexistence. Ecol Monogr 59:1–20
Brown JS, Kotler BP, Mitchell WA (1994) Foraging theory, patch use and the structure of a Negev desert granivore community. Ecology 75:2286–2300
Charnov EL (1976) Optimal foraging: the marginal value theorem. Theor Pop Biol 9:129–136
Chesson PL, Warner RR (1981) Environmental variability promotes coexistence in lottery competitive system. Am Nat 117:923–943
Colwell RK, Fuentes ER (1975) Experimental studies of the niche. Annu Rev Ecol Syst 6:281–310
Cornell HV, Lawton JH (1992) Species interactions, local and regional processes, and limits to the richness of ecological communities: a theoretical perspective. J Anim Ecol 61:1–12
Danin A (1978) Plant species diversity and plant succession in a sandy area in the Northern Negev. Flora 167:400–422
French AR (1993) Physiological ecology of the Heteromyidae: economics of energy and water utilization. In: Genoways HH, Brown JH (eds) Biology of the heteromyidae. Am Soc Mammal Spec Publ 10, Lawrence, pp 509–538
Fretwell SD (1972) Populations in a seasonal environment. Princeton University Press, Princeton
Fretwell SD, Lucas HLJ (1970) On territorial behavior and other factors influencing habitat distribution in birds. Acta Biotheor 14:16–36
Frye R (1983) Experimental field evidence of interspecific aggression between two species of kangaroo rat (Dipodomys). Oecologia 59:74–78
Giller PS (1984) Community structure and the niche. Chapman and Hall, London
Grant PR (1972) Interspecific competition among rodents. Annu Rev Ecol Syst 3:79–106
Holling CS (1992) Cross-scale morphology, geometry, and dynamics of ecosystems. Ecol Monogr 62:447–502
Hoover KD, Whitford WG, Flavill P (1977) Factors influencing the distribution of two species of Perognathus. Ecology 58:877–884
Hutchinson GE (1957) Concluding remarks. Cold Spring Harbor Symp Quant Biol 22:415–427
Kotler BP, Brown JS (1988) Environmental heterogeneity and the coexistence of desert rodents. Annu Rev Ecol Syst 19:281–307
Kotler BP, Brown JS (1990) Rates of seed harvest by two species of gerbilline rodents. J Mammal 71:591–596
Kotler BP, Brown JS, Subach A (1993) Mechanisms of species coexistence of optimal foragers: temporal partitioning by two species of sand dune gerbils. Oikos 67: 548–556
Levins R (1979) Coexistence in a variable environment. Am Nat 114:765–783
Linder Y (1988) Seasonal differences in thermoregulation in G. allenbyi and G. pyramidum and their contribution to energy budget (in Hebrew with an English abstract). MS thesis, Ben-Gurion University Negev, Beer-Sheva
MacArthur RH (1958) Population ecology of some warblers of northeastern coniferous forests. Ecology 39:599–619
MacArthur RH (1964) Environmental factors affecting bird species diversity. Am Nat 98: 387–397
MacArthur RH, Levins R (1964) Competition, habitat selection, and character displacement in a patchy environment. Proc Natl Acad Sci USA 51:1207–1210
MacArthur RH, Recher H, Cody M (1966) On the relation between habitat selection and species diversity. Am Nat 100:319–332
May RM (1973) Stability and complexity in model ecosystems. Princeton University Press, Princeton
M’Closkey RT (1983) Desert rodent activity: response to seed production by two perennial plant species. Oikos 41:233–238
Menge JL, Menge BA (1974) Role of resource allocation, aggression, and spatial heterogeneity in coexistence in two competing intertidal starfish. Ecol Monogr 44:189–209
Mitchell WA, Abramsky Z, Kotler BP, Pinshow B, Brown JS (1990) The effect of competition on foraging activity in desert rodents: theory and experiments. Ecology 71:844–854
Nelson J, Chew R(1977) Factors affecting seed reserves in the soil of a Mojave Desert ecosystem, Rock Valley, Nye County, Nevada. Am Midl Nat 97:300–320
Park T (1962) Beetles, competition and populations. Science 138:1369–1375
Pianka ER (1974) Niche overlap and diffuse competition. Proc Natl Acad Sci USA 71:2141–2145
Pimm SL, Rosenzweig ML, Mitchell WA (1985) Competition and food selection: field tests of a theory. Ecology 66:798–807
Price MV (1978) The role of microhabitat specialization in structuring desert rodent communities. Ecology 58:1393–1399
Price MV (1986) Structure of desert rodent communities: a critical review of questions and approaches. Am Zool 26:39–49
Price MV, Reichman OJ (1987) Distribution of seeds in Sonoran Desert soils: implications for heteromyid rodent foraging. Ecology 68:1797–1811
Reichman OJ (1975) Relation of desert rodent diets to available resources. J Mammal 56:731–751
Reichman OJ (1984) Spatial and temporal variation in seed distributions in desert soils. J Biogeogr 11:1–11
Reichman OJ, Price MV (1993) Ecological aspects of heteromyid foraging. In: Genoways HH, Brown JH (eds) Biology of the heteromyidae. Am Soc Mammal Spec Publ 10, Lawrence, pp 539–574
Rosenzweig ML (1973) Habitat selection experiments with a pair of coexisting heteromyid rodent species. Ecology 54:111–117
Rosenzweig ML (1974) On the optimal aboveground activity of bannertail kangeroo rats. J Mammal 55:193–199
Rosenzweig ML (1977) Coexistence and diversity in heteromyid rodents. In: Stonehouse B, Perrins C (eds) Evolutionary biology. Macmillan, London, pp 89–99
Rosenzweig ML (1981) A theory of habitat selection. Ecology 62:327–335
Rosenzweig ML (1985) Some theoretical aspects of habitat selection. In: Cody M (ed) Habitat selection in birds. Academic Press, New York, pp 517–540
Rosenzweig ML (1991) Habitat selection and population interactions: the search for mechanisms. Am Nat 137:S5–S28
Rosenzweig ML, Abramsky Z (1986) Centrifugal community organization. Oikos 46:339–348
Rosenzweig ML, Sterner P (1970) Population ecology of desert rodent communities: body size and seed husking as a basis for heteromyid coexistence. Ecology 51:217–224
Rosenzweig ML, Winakur J (1969) Population ecology of desert rodent communities: habitat and environmental complexity. Ecology 50:558–572
Schmidly DJ, Wilkins KT, Derr JN (1993) Biogeography. In: Genoways HH, Brown JH (eds) Biology of the heteromyidae. Am Soc Mammal Spec Publ 10, Lawrence, pp 319–356
Schoener TW (1974a) Resource partitioning in ecological communities. Science 185:27–39
Schoener TW (1974b) The comparison hypothesis and temporal resource partitioning. Proc Natl Acad Sci USA 71:4169–4172
Schoener TW (1986a) Resource partitioning. In: Anderson D, Kikkawa J (eds) Community ecology: pattern and process. Blackwell, Oxford, pp 91–126
Schoener TW (1986b) Mechanistic approaches to community ecology: a new reductionism? Am Zool 26:81–106
Shkolnik A (1971) Diurnal activity in a small desert rodent. Int J Biometeor 15:115–120
Stewart FM, Levin BR (1973) Partitioning of resources and the outcome of interspecific competition: a model and some general considerations. Am Nat 107:171–198
Vance RR (1984) Interference competition and the coexistence of two competitors on a single limiting resource. Ecology 65:1349–1357
Whittaker RH, Levin SA (eds) (1975) Niche theory and application. Dowden, Hutchinson and Ross, New York
Zahavi A, Wharman J (1957) The cytotaxonomy, ecology, and evolution of the gerbils and jirds of Israel (Rodentia: Gerbillinae). Mammalia 21:341–380
Ziv Y (1991) Mechanisms of coexistence, based on theories of optimal foraging and habitat selection, between Gerbilus allenbyi and G. pyramidum in the sandy habitats of the Western Negev (in Hebrew with an English abstract). MS thesis, Ben-Gurion University Negev, Beer-Sheva
Ziv Y, Abramsky Z, Kotler BP, Subach A (1993) Interference competition, and temporal and habitat partitioning in two gerbil species. Oikos 66:237–246
Ziv Y, Kotler BP, Abramsky Z, Rosenzweig ML (1995) Foraging efficiencies of competing rodents: why do gerbils exhibit shared-preference habitat selection? Oikos 73:260–268
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Ziv, Y., Smallwood, J.A. (2000). Gerbils and Heteromyids — Interspecific Competition and the Spatio-Temporal Niche. In: Halle, S., Stenseth, N.C. (eds) Activity Patterns in Small Mammals. Ecological Studies, vol 141. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-18264-8_11
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DOI: https://doi.org/10.1007/978-3-642-18264-8_11
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