Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-28T02:06:27.906Z Has data issue: false hasContentIssue false

The Effect of Habitat Fragmentation on Cyclic Populations withEdge Behaviour

Published online by Cambridge University Press:  28 November 2013

T. Gauduchon
Affiliation:
Agrocampus Ouest, 65 rue de Saint Brieuc, CS84215 - 35042 Rennes Cedex, France
S. Strohm
Affiliation:
Mathematics and Statistics, Okanagan College, 583 Duncan Ave W, Penticton, BC, V2A 8E1 Canada
R. C. Tyson*
Affiliation:
Mathematics and Statistics, IKBSAS 5 SCI, University of British Columbia Okanagan, 3333 University Way, Kelowna, BC, V1V 1V7, Canada
*
Corresponding author. E-mail: [email protected]
Get access

Abstract

Habitat fragmentation is an important area of concern in species conservation. Habitatfragmentation can affect population distributions through reductions in suitable habitat,and through organism responses to different habitat types and the transitions betweenthem. In earlier work, the effect of habitat fragmentation on cyclic populations wasinvestigated in the context of populations that show no behavioural response to theinterface between habitat types. In this paper, we extend the earlier work by addingedge-mediated behaviour to the models. That is, we investigate the dynamics that resultwhen oscillatory predator and prey species also exhibit behavioural responses to habitatinterfaces. Our results show generally that habitat loss decreases the amplitude and theaverage density of the prey and predator populations, but that most of the reponsesobserved in the two models exhibit marked differences. This work highlights the complexityof the interplay between population cycles, habitat fragmentation, and edge-mediatedbehaviour, and the need to study such systems in greater detail.

Type
Research Article
Copyright
© EDP Sciences, 2013

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Akcakaya, H.R., Population cycles of mammals: evidence for a ratio-dependent hypothesis, Ecological Monographs, 62 (1992), No. 1, 119142. CrossRefGoogle Scholar
A. BlSssle, Stochastic Modelling of Animal Movement using Intermittent Search Patterns, Master’s thesis, University of British Columbia, Kelowna, BC, Canada, 2013.
Chapman, D.S., Dytham, C., Oxford, G.S., Landscape and fine-scale movements of a leaf beetle: The importance of boundary behaviour, Oecologia, 154 (2007), No. 1, 5564. CrossRefGoogle Scholar
Costa, A., Min, A., Boone, C.K., Kendrick, A.P., Murphy, R.J., Sharpee, W.C., Raffa, K.F., Reeve, J.D., Dispersal and edge behaviour of bark beetles and predators inhabiting red pine plantations, Agricultural and Forest Entomology, 15 (2013), No. 1, 111. CrossRefGoogle Scholar
Cronin, J.T., Habitat edges, within-patch dispersion of hosts, and parasitoid oviposition behavior, Ecology, 90 (2009), No. 1, 196207. CrossRefGoogle ScholarPubMed
L. Edelstein-Keshet, Mathematical models in biology, Society for Industrial and Applied Mathematics, Philadelphia, 2005.
Fahrig, L., Effects of habitat fragmentation on biodiversity, Annual Review of Ecology Evolution and Systematics, 34 (2003), 487-515. CrossRefGoogle Scholar
Fussmann, G.F., Blasius, B., Community response to enrichment is highly sensitive to model structure, Biology Letters, 1 (2005), 9-12. CrossRefGoogle ScholarPubMed
Gurarie, E., Suutarinen, J., Kojola, I., Ovaskainen, O., Summer movements, predation and habitat use of wolves in human modified boreal forests, Oecologia, 165 (2011), 891-903. CrossRefGoogle ScholarPubMed
Haughland, D.L., Larsen, K.W., Exploration correlates with settlement: Red squirrel dispersal in contrasting habitats, Journal of Animal Ecology, 73 (2004), 1024-1034. CrossRefGoogle Scholar
Inman, R.M., Packyla, M.L., Inman, K.H., Mccue, A.J., White, G.C., Persson, J., Aber, B.C., Orme, M.L., Alt, K.L., Kain, S.L., Fredrick, J.A., Oakleaf, B.J., Sartorius, S.S., Spacial ecology of wolverines at the southern periphery of distribution, The Journal of Wildlife Management, 76 (2012), No. 4, 778792. CrossRefGoogle Scholar
Jackson, H.B., Baum, K.A., Robert, T., Cronin, J.T., Habitat-Specific Movement and Edge-Mediated Behavior of the Saproxylic Insect Odontotaenius disjunctus (Coleoptera: Passalidae), Environmental Entomology, 38 (2009), No. 5, 14111422. CrossRefGoogle Scholar
Keim, J.L., DeWitt, P.D., Lele, S.R., Predators choose prey over prey habitats: evidence from a lynx-hare system, Ecological Applications, 21 (2011), No. 4, 10111016. CrossRefGoogle ScholarPubMed
Koehler, G.M., Maletzke, B.T., Von Kienast, J.A., Aubry, K.B., Wielgus, R.B., Naney, R.H., Habitat fragmentation and the persistence of lynx populations in Washington State, Journal of Wildlife Management, 72 (2008), No. 7, 15181524. Google Scholar
M. Kot, Elements of mathematical ecology, Cambridge University Press, Cambridge, U.K., New York, 2001.
C.J. Krebs, S. Boutin, R. Boonstra (eds.), Ecosystem dynamics of the boreal forest: The kluane project, Oxford University Press, Oxford; New York, 2001.
Maciel, G.A., Lutscher, F., How individual movement response to habitat edges affects population persistence and spatial spread, American Naturalist, 182 (2013), No. 1, 4252. CrossRefGoogle Scholar
McCann, N.P., Moen, R.A., Mapping potential core areas for lynx (lynx canadensis) using pellet counts from snowshoe hares (lepus americanus) and satellite imagery, Canadian Journal of Zoology, 89 (2011), 509-516. CrossRefGoogle Scholar
H.W. McKenzie, Linear features impact predator-prey encounters: Analysis with first passage time, Master’s thesis, University of Alberta, Edmonton, AB, Canada, 2006.
Murdoch, W.W., Kendall, B.E., Nisbet, R.M., Briggs, C.J., McCauley, E., Bolser, R., Single-species models for many-species food webs, Nature, 417 (2002), 541-543. CrossRefGoogle ScholarPubMed
Murray, D.L., Steury, T.D., Roth, J.D., Assessment of canada lynx research and conservation needsin the southern range: another kick at the cat, Journal of Wildlife Management, 72 (2008), No. 7, 14631472. CrossRefGoogle Scholar
J.D. Murray, Mathematical biology, Springer-Verlag, Berlin, New York, 1989.
Ovaskainen, O., Cornell, S.J., Biased movement at a boundary and conditional occupancy times for diffusion processes, Journal of Applied Probability, 40 (2003), 557-580. CrossRefGoogle Scholar
Reeve, J.D., Cronin, J.T., Edge behaviour in a minute parasitic wasp, Journal of Animal Ecology, 79 (2010), No. 2, 483490. CrossRefGoogle Scholar
Ries, L., Debinski, D.M., Butterfly responses to habitat edges in the highly fragmented prairies of central Iowa, Journal of Animal Ecology, 70 (2001), 840852. CrossRefGoogle Scholar
Rueness, E.K., Stenseth, N.C., O’Donoghue, M., Boutin, S., Ellegren, H., Jakobsen, K.S., Ecological and genetic spacial structuring in the Canadian lynx, Nature, 425 (2003), No. 6953, 6972. CrossRefGoogle Scholar
Ryall, K.L., Fahrig, L., Response of predators to loss and fragmentation of prey habitat: A review of theory, Ecology, 87 (2006), No. 5, 10861093. CrossRefGoogle ScholarPubMed
Senger, S., Tyson, R., Roitberg, B.D., Thistlewood, H.M.A., Harestasd, A.S., Chandler, M.T., Influence of habitat structure and resource availability on the movements of rhagoletis indifferens (Diptera: Tephritidae, Environmental Entomology, 38 (2009), 823-835. CrossRefGoogle ScholarPubMed
Strohm, S., Tyson, R., The effect of habitat fragmentation on cyclic population dynamics: A numerical study, Bulletin of Mathematical Biology, 71 (2009), 1323-1348. CrossRefGoogle ScholarPubMed
Strohm, S., Tyson, R.C., The effect of habitat fragmentation on cyclic population dynamics: A reduction to ordinary differential equations, Theoretical Ecology, 5 (2011), No. 4, 495516. CrossRefGoogle Scholar
Tyson, R., Haines, S., Hodges, K.E., Modelling the canada lynx and snowshoe hare 1population cycle: The role of specialist predators, Theoretical Ecology, 3 (2010), 97-111. CrossRefGoogle Scholar
Tyson, R., Thistlewood, H., Judd, G.J.R., Modelling dispersal of sterile male codling moths, cydia pomonella, across orchard boundaries, Ecological Modelling, 205 (2007), 112. CrossRefGoogle Scholar
Villis, N.O., Shape of patch edges affects edge permeability for meadow voles, Ecological Applications, 22 (2012), No. 6, 18271837. Google Scholar
Ylonen, H., Pech, R., Davis, S., Heterogeneous landscapes and the role of refuge on the population dynamics of a specialist predator and its prey, Bulletin of Mathematical Biology, 59 (2003), 107137. Google Scholar