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2 - Landscape connectivity: a return to the basics

Published online by Cambridge University Press:  24 May 2010

Kevin R. Crooks
Affiliation:
Colorado State University
M. Sanjayan
Affiliation:
The Nature Conservancy, Virginia
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Summary

INTRODUCTION

In the decade or so since the concept was formalized in landscape ecology (Taylor et al. 1993) the meaning of the term “landscape connectivity” has become rather diffuse and ambiguous. Many researchers continue to ignore key elements of the original concept, which greatly diminishes its potential utility for land management and the conservation of biodiversity. As originally defined, landscape connectivity is “the degree to which the landscape facilitates or impedes movement among resource patches” (Taylor et al. 1993; see also With et al. 1997). This definition emphasizes that the types, amounts, and arrangement of habitat or land use on the landscape influence movement and, ultimately, population dynamics and community structure. Landscape connectivity thus combines a description of the physical structure of the landscape with an organism's response to that structure. In contrast, common usage generally emphasizes only the structural aspect, where landscape connectivity is simply equated with linear features of the landscape that promote dispersal, such as corridors. Moreover, most commonly employed measures of connectivity focus only on how patch area and inter-patch distances affect movement (e.g., Moilanen and Hanski Chapter 3); such measures ignore the rich complexity of how organisms interact with spatial heterogeneity that may ultimately affect dispersal and colonization success (e.g., interactions with patch boundaries, matrix heterogeneity: Wiens et al. 1993; Wiens 1997; Jonsen and Taylor 2000a).

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Publisher: Cambridge University Press
Print publication year: 2006

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References

Andrén, H. 1994. Effects of habitat fragmentation on birds and mammals in landscapes with different proportions of suitable habitat: a review. Oikos 71:355–366CrossRefGoogle Scholar
Bélisle, M., and Desrochers, A.. 2002. Gap-crossing decisions by forest birds: an empirical basis for parameterizing spatially-explicit, individual-based models. Landscape Ecology 17:219–231CrossRefGoogle Scholar
Breininger, D. R., and Carter, G. M.. 2003. Territory quality transitions and source–sink dynamics in a Florida scrub-jay population. Ecological Applications 13:516–529CrossRefGoogle Scholar
Chalfoun, A. D., Thompson, F. R., and Ratnaswamy, M. J.. 2002. Nest predators and fragmentation: a review and meta-analysis. Conservation Biology 16:306–318CrossRefGoogle Scholar
Cooper, C. B., Walters, J. R., and Priddy, J.. 2002. Landscape patterns and dispersal success: simulated population dynamics in the brown treecreeper. Ecological Applications 6:1576–1587CrossRefGoogle Scholar
Dale, V. H., Pearson, S. M., Offerman, H. L., and O'Neill, R. V.. 1994. Relating patterns of land-use change to faunal biodiversity in the central Amazon. Conservation Biology 8:1027–1036CrossRefGoogle Scholar
Desrochers, A., L. Rochefort, and J. P. L. Savard. 1998. Avian recolonization of eastern Canadian bogs after peat mining. Canadian Journal of Zoology 76:989–997CrossRef
Fahrig, L. 1997. Relative effects of habitat loss and fragmentation on species extinction. Journal of Wildlife Management 61:603–610CrossRefGoogle Scholar
Fahrig, L. 2001. How much habitat is enough?Biological Conservation 100:65–74CrossRefGoogle Scholar
Ferreras, P. 2001. Landscape structure and asymmetrical inter-patch connectivity in a metapopulation of the endangered Iberian lynx. Biological Conservation 100:125–136CrossRefGoogle Scholar
Gardner, R. H., Milne, B. T., Turner, M. G., and O'Neill, R. V.. 1987. Neutral models for the analysis of broad-scale landscape pattern. Landscape Ecology 1:19–28CrossRefGoogle Scholar
Goodwin, B. J., and Fahrig, L. 2002. Effect of landscape structure on the movement behaviour of a specialized goldenrod beetle, Trirhabda borealis. Canadian Journal of Zoology 80:24–35CrossRefGoogle Scholar
Gunderson, L. H., and Holling, C. S.. 2002. Panarchy: Understanding Transformations in Human and Natural Systems. Washington DC: Island Press.Google Scholar
Gustafson, E. J. 1998. Quantifying landscape spatial pattern: what is state of the art?Ecosystems 1:143–156CrossRefGoogle Scholar
Gustafson, E. J., and Gardner, R. H.. 1996. The effect of landscape heterogeneity on the probability of patch colonization. Ecology 77:94–107CrossRefGoogle Scholar
Hannon, S. J., and F. K. A. Schmiegelow. 2000. Corridors may not improve the conservation value of small reserves for most boreal birds. Ecological Applications. 12:1457–1468
Hansen, A. J., and Urban, D. L.. 1992. Avian response to landscape pattern: the role of species' life histories. Landscape Ecology 7:163–180CrossRefGoogle Scholar
Hanski, I. 1999. Habitat connectivity, habitat continuity, and metapopulations in dynamic landscapes. Oikos 77:209–219CrossRefGoogle Scholar
Hanski, I., and Ovaskainen, O.. 2002. Extinction debt at extinction threshold. Conservation Biology 16:666–673CrossRefGoogle Scholar
Hinsley, S. A. 2000. The costs of multiple patch use by birds. Landscape Ecology 15:765–775CrossRefGoogle Scholar
Johnson, W. C., and Collinge, S. K.. 2004. Landscape effects on black-tailed prairie dog colonies. Biological Conservation 115:487–497CrossRefGoogle Scholar
Jonsen, I. D., and Taylor, P. D.. 2000a. Landscape structure and fine-scale movements of Calopterygid damselflies. Oikos 88:553–562CrossRefGoogle Scholar
Jonsen, I. D., and Taylor, P. D.. 2000b. Calopteryx damselfly dispersions arising from multi-scale responses to landscape structure. Conservation Ecology4:4. Available online at http://www.consecol.org/vol4/iss2/art4Google Scholar
Jonsen, I. D., Myers, R. A., and Flemming, J. M. 2003. Meta-analysis of animal movement using state-space models. Ecology 84:3055–3063CrossRefGoogle Scholar
Keitt, T. H., Urban, D. L, and Milne, B. T.. 1997. Detecting critical scales in fragmented landscapes. Conservation Ecology1:4. Available online at http://www.consecol.org/vol1/iss1/art4Google Scholar
Lindenmayer, D. B., Lacy, R. C, and Pope, M. L.. 2000. Testing a simulation model for population viability analysis. Ecological Applications 10:580–597CrossRefGoogle Scholar
Man, A., Law, R, and Polunin, N. V. C. 1995. Role of marine reserves in recruitment to reef fisheries: a metapopulation model. Biological Conservation 71:197–204CrossRefGoogle Scholar
Milne, B. T., Johnston, K. M., and Forman, R. T. T. 1989. Scale-dependent proximity of wildlife habitat in a spatially neutral Bayesian model. Landscape Ecology 2:101–110CrossRefGoogle Scholar
Moilanen, A., and Nieminen, M. 2002. Simple connectivity measures in spatial ecology. Ecology 83:1131–1145CrossRefGoogle Scholar
Pearson, S. M., Turner, M. G., Gardner, R. H., and O'Neill, R. V.. 1996. An organism-based perspective of habitat fragmentation. Pp. 77–95 in Szaro, R. C. and Johnston, D. W. (eds.) Biodiversity in Managed Landscapes: Theory and Practice. Oxford, UK: Oxford University Press.Google Scholar
Peterken, G. 2002. Reversing the Habitat Fragmentation of British Woodlands. Report, World Wildlife Federation–UK Research Centre, Surrey, UK. Available online at http://www.wwf-uk.org/filelibrary/pdf/reversing_fragmentation.pdfGoogle Scholar
Pitelka, L. F., and the Plant Migration Workshop Group, . 1997. Plant migration and climate change. American Scientist 85:464–473Google Scholar
Pither, J., and Taylor, P. D.. 1998. An experimental assessment of landscape connectivity. Oikos 83:166–174CrossRefGoogle Scholar
Pither, J., and Taylor, P. D.. 2000. Directional and fluctuating asymmetry in the black-winged damselfly Calopteryx maculata (Beauvois) (Odonata: Calopterygidae). Canadian Journal of Zoology 78:1740–1748CrossRefGoogle Scholar
Ricketts, T. 2001. The matrix matters: effective isolation in fragmented landscapes. American Naturalist 158:87–99CrossRefGoogle ScholarPubMed
Robichaud, I., Villard, M. A., and Machtans, C. S.. 2002. Effects of forest regeneration on songbird movements in a managed forest landscape of Alberta, Canada. Landscape Ecology 17:247–262CrossRefGoogle Scholar
Roland, J., Keyghobadi, N., and Fownes, S.. 2000. Alpine Parnassius butterfly dispersal: effects of landscape and population size. Ecology 81:1642–1653CrossRefGoogle Scholar
Schooley, R. L., and Wiens, J. A.. 2003. Finding habitat patches and directional connectivity. Oikos 102:559–570CrossRefGoogle Scholar
Schultz, C. B. 1998. Dispersal behavior and its implications for reserve design in a rare Oregon butterfly. Conservation Biology 12:284–292CrossRefGoogle Scholar
Sekercioglu, C. H. 2002. Effects of forestry practices on vegetation structure and bird community of Kibale National Park, Uganda. Biological Conservation 107:229–240CrossRefGoogle Scholar
Selonen, V., and Hanski, I. K.. 2003. Movements of the flying squirrel Pteromys volans in corridors and in matrix habitat. Ecography 26:641–651CrossRefGoogle Scholar
South West Wildlife Trusts, . 2004. Rebuilding Landscapes for Wildlife and People: An Introductory Primer. Available online at http://www.swenvo.org.uk/nature-map/solidusGoogle Scholar
Stith, B. M., J. W. Fitzpatrick, G. E. Woolfenden, and B. Pranty. 1996. Classification and conservation of metapopulations: a case study of the Florida Scrub Jay. Pp. 187–215 in McCullough, D. R. (ed.) Metapopulations and Wildlife Conservation. Washington DC: Island Press.Google Scholar
Taylor, P. D., and Merriam, G.. 1995. Wing morphology of a forest damselfly is related to landscape structure. Oikos 73:43–48CrossRefGoogle Scholar
Taylor, P. D., Fahrig, L., Henein, K., and Merriam, G.. 1993. Connectivity is a vital element of landscape structure. Oikos 68:571–572CrossRefGoogle Scholar
Tewksbury, J. J., Levey, D. J., Haddad, N. M., et al. 2002. Corridors affect plants, animals, and their interactions in fragmented landscapes. Proceedings of the National Academy of Sciences of the USA 99:12923–12926CrossRefGoogle ScholarPubMed
Tilman, D., May, R. M., Lehman, C. L., and Nowak, M. A.. 1994. Habitat destruction and the extinction debt. Nature 371:65–66CrossRefGoogle Scholar
Tischendorf, L., and Fahrig, L.. 2000. How should we measure landscape connectivity?Landscape Ecology 15:633–641CrossRefGoogle Scholar
Urban, D., and Keitt, T.. 2001. Landscape connectivity: a graph-theoretic perspective. Ecology 82:1205–1218CrossRefGoogle Scholar
Varkonyi, G., Kuussaari, M., and Lappalainen, H.. 2003. Use of forest corridors by boreal Xestia moths. Oecologia 137:466–474CrossRefGoogle ScholarPubMed
Warren, M. S., Hill, J. K., Thomas, J. A., et al. 2001. Rapid consequences of British butterflies to opposing forces of climate and habitat change. Nature 414:65–69CrossRefGoogle Scholar
Watts, K., Griffiths, M., Quine, C., Ray, D., and Humphrey, J. W. 2005. Towards a Woodland Habitat Network for Wales, Contract Science Report No. 686. Bangor, UK: Countryside Council for Wales.Google Scholar
Wiens, J. A. 1997. Metapopulation dynamics and landscape ecology. Pp. 43–62 in Hanski, I. A., and Gilpin, M. E. (eds.) Metapopulation Biology: Ecology, Genetics, and Evolution. San Diego, CA: Academic Press.Google Scholar
Wiens, J. A., Stenseth, N. C., Horne, B., and Ims, R. A.. 1993. Ecological mechanisms and landscape ecology. Oikos 66:369–380CrossRefGoogle Scholar
With, K. A. 1997. The application of neutral landscape models in conservation biology. Conservation Biology 11:1069–1080CrossRefGoogle Scholar
With, K. A. 2002. Using percolation theory to assess landscape connectivity and effects of habitat fragmentation. Pp. 105–130 in Gutzwiller, K. J., (ed.) Applying Landscape Ecology in Biological Conservation. New York: Springer-Verlag.CrossRefGoogle Scholar
With, K. A., and Crist, T. O.. 1995. Critical thresholds in responses to landscape structure. Ecology 76:2446–2459CrossRefGoogle Scholar
With, K. A., and King, A. W.. 1999a. Dispersal success on fractal landscapes: a consequence of lacunarity thresholds. Landscape Ecology 14:73–82CrossRefGoogle Scholar
With, K. A., and King, A. W.. 1999b. Extinction thresholds for species in fractal landscapes. Conservation Biology 13:314–326CrossRefGoogle Scholar
With, K. A., Gardner, R. H., and Turner, M. G.. 1997. Landscape connectivity and population distributions in heterogeneous environments. Oikos 78:151–169CrossRefGoogle Scholar
Woodford, J. E., and Meyer, M. W. 2003. Impact of lakeshore development on green frog abundance. Biological Conservation 110: 277–284CrossRefGoogle Scholar
Woodland Trust, . 2000. Woodland Biodiversity: Expanding our Horizons. Available online at http://www.woodland-trust.org.uk/publications/publicationsmore/expandingourhorizons.pdfGoogle Scholar
Woodland Trust, . 2002. Space for Nature: Landscape-Scale Action for Woodland Biodiversity. Available online at http://www.woodland-trust.org.uk/publications/publicationsmore/space.pdfGoogle Scholar

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