Book contents
- Frontmatter
- Contents
- List of contributors
- Foreword
- Acknowledgements
- 1 A plea for quantitative targets in biodiversity conservation
- 2 Setting conservation targets: past and present approaches
- 3 Designing studies to develop conservation targets: a review of the challenges
- 4 Testing the efficiency of global-scale conservation planning by using data on Andean amphibians
- 5 Selecting biodiversity indicators to set conservation targets: species, structures, or processes?
- 6 Selecting species to be used as tools in the development of forest conservation targets
- 7 Bridging ecosystem and multiple species approaches for setting conservation targets in managed boreal landscapes
- 8 Thresholds, incidence functions, and species-specific cues: responses of woodland birds to landscape structure in south-eastern Australia
- 9 Landscape thresholds in species occurrence as quantitative targets in forest management: generality in space and time?
- 10 The temporal and spatial challenges of target setting for dynamic habitats: the case of dead wood and saproxylic species in boreal forests
- 11 Opportunities and constraints of using understory plants to set forest restoration and conservation priorities
- 12 Setting conservation targets for freshwater ecosystems in forested catchments
- 13 Setting quantitative targets for recovery of threatened species
- 14 Allocation of conservation efforts over the landscape: the TRIAD approach
- 15 Forest landscape modeling as a tool to develop conservation targets
- 16 Setting targets: tradeoffs between ecology and economics
- 17 Setting, implementing, and monitoring targets as a basis for adaptive management: a Canadian forestry case study
- 18 Putting conservation target science to work
- Index
- References
9 - Landscape thresholds in species occurrence as quantitative targets in forest management: generality in space and time?
Published online by Cambridge University Press: 05 June 2012
Book contents
- Frontmatter
- Contents
- List of contributors
- Foreword
- Acknowledgements
- 1 A plea for quantitative targets in biodiversity conservation
- 2 Setting conservation targets: past and present approaches
- 3 Designing studies to develop conservation targets: a review of the challenges
- 4 Testing the efficiency of global-scale conservation planning by using data on Andean amphibians
- 5 Selecting biodiversity indicators to set conservation targets: species, structures, or processes?
- 6 Selecting species to be used as tools in the development of forest conservation targets
- 7 Bridging ecosystem and multiple species approaches for setting conservation targets in managed boreal landscapes
- 8 Thresholds, incidence functions, and species-specific cues: responses of woodland birds to landscape structure in south-eastern Australia
- 9 Landscape thresholds in species occurrence as quantitative targets in forest management: generality in space and time?
- 10 The temporal and spatial challenges of target setting for dynamic habitats: the case of dead wood and saproxylic species in boreal forests
- 11 Opportunities and constraints of using understory plants to set forest restoration and conservation priorities
- 12 Setting conservation targets for freshwater ecosystems in forested catchments
- 13 Setting quantitative targets for recovery of threatened species
- 14 Allocation of conservation efforts over the landscape: the TRIAD approach
- 15 Forest landscape modeling as a tool to develop conservation targets
- 16 Setting targets: tradeoffs between ecology and economics
- 17 Setting, implementing, and monitoring targets as a basis for adaptive management: a Canadian forestry case study
- 18 Putting conservation target science to work
- Index
- References
Summary
INTRODUCTION
Simulation models predict that habitat loss may reach a threshold level below which ecological processes change abruptly (Fahrig 1998; With and King 1999; Flather and Bevers 2002). Effects of fragmentation sensu stricto are then detected, whereby increasing distances among patches and matrix resistance reduce the likelihood of recolonization after local extinctions (Lande 1987; With and King 1999). By definition, models simplify reality; therefore, they do not always represent appropriate metaphors for real landscapes because they tend to assume sharply contrasted habitat mosaics. None the less, different species perceive the same landscape differently and those specializing on habitat types dramatically altered by management may exhibit actual fragmentation effects and species-specific thresholds.
Surprisingly few studies have examined the landscape-scale effects of forest management on animals and plants. Previous landscape-scale studies have mainly examined species response to different landscape contexts or landscape structures in forests fragmented by agriculture (see Chapter 8, this volume, for a review). Managed forest landscapes are thought to be more permeable to the movements of vertebrate forest animals because contrasts among forest stands are generally softer than between forests and cropfields or pastures, for example. Indeed, fragmentation effects have mainly been detected in forests fragmented by agriculture or in island archipelagoes (Mönkkönen and Reunanen 1999). Clearcuts may become relatively permeable to forest bird movements as soon as the regeneration provides some cover (Sieving et al. 1996), although juveniles may not move across them as readily as adults.
- Type
- Chapter
- Information
- Setting Conservation Targets for Managed Forest Landscapes , pp. 185 - 206Publisher: Cambridge University PressPrint publication year: 2009
References
1994. Effects of habitat fragmentation on birds and mammals in landscapes with different proportions of suitable habitat: a review. Oikos 71:355–66.CrossRefGoogle Scholar
2004. Habitat thresholds and effects of forest landscape change on the distribution and abundance of black grouse and capercaillie. Ecological Bulletins 51:173–87.Google Scholar
, and . 2003. Interpretation of landscape pattern and habitat change for local indicator species using satellite imagery and geographical information system data in New Brunswick, Canada. Canadian Journal of Forest Research 33:1821–31.CrossRefGoogle Scholar
, , , and . 2006a. The importance of spatial autocorrelation, extent and resolution in predicting forest bird occurrence. Ecological Modelling 191:197–224.CrossRefGoogle Scholar
, , and . 2006b. Independent effects of fragmentation on forest songbirds: an organism-based approach. Ecological Applications 16:1076–89.CrossRefGoogle ScholarPubMed
, and . 2007a. Thresholds in songbird occurrence in relation to landscape structure. Conservation Biology 21:1046–58.CrossRefGoogle ScholarPubMed
, , and . 2007b. Uneven rates of wildlife change as a source of bias in roadside wildlife surveys. Journal of Wildlife Management 71:2266–73.CrossRefGoogle Scholar
and . 2004. Avian habitat evaluation: should counting birds count?Frontiers in Ecology and the Environment 2:403–10.CrossRefGoogle Scholar
2003. Is dispersal distance of birds proportional to territory size?Canadian Journal of Zoology 81:195–202.CrossRefGoogle Scholar
and . 2007. Landscape-level thresholds and newt conservation. Ecological Applications 17:302–9.CrossRefGoogle ScholarPubMed
, , et al. 2002. A removal model for estimating detection probabilities from point-count surveys. Auk 119:414–25.CrossRefGoogle Scholar
1998. When does fragmentation of breeding habitat affect population survival?Ecological Modelling 105:273–92.CrossRefGoogle Scholar
and . 2002. Patchy reaction-diffusion and population abundance: the relative importance of habitat amount and arrangement. American Naturalist 159:40–56.Google ScholarPubMed
and . 2005. Thresholds in forest bird response to habitat alteration as quantitative targets for conservation. Conservation Biology 19:1168–80.CrossRefGoogle Scholar
and . 2004. Do empirical thresholds truly reflect species tolerance to habitat alteration?Ecological Bulletins 51:163–71.Google Scholar
and . 2005. Predicting species distribution: offering more than simple habitat models. Ecology Letters 8:993–1009.CrossRefGoogle Scholar
, and . 2004. Critical thresholds associated with habitat loss for two vernal pool-breeding amphibians. Ecological Applications 14:1547–53.CrossRefGoogle Scholar
2005. The concept and utility of ecological thresholds in biodiversity conservation. Biological Conservation 124:301–10.CrossRefGoogle Scholar
and 2005. Monitoring programs need to take into account imperfect species detectability. Basic and Applied Ecology 5:65–73.CrossRefGoogle Scholar
, and . 2005. Demographic responses by birds to forest fragmentation. Conservation Biology 19:1537–46.CrossRefGoogle Scholar
1987. Extinction thresholds in demographic models of territorial populations. American Naturalist 130:624–35.CrossRefGoogle Scholar
, , and . 2002. Spatial autocorrelation and autoregressive models in ecology. Ecological Monographs 72:445–63.CrossRefGoogle Scholar
, , , and . 2003. Estimating site occupancy, colonization and local extinction when a species is detected imperfectly. Ecology 84:2200–7.CrossRefGoogle Scholar
and . 1999. On critical thresholds in landscape connectivity: a management perspective. Oikos 84:302–5.CrossRefGoogle Scholar
2003. Estimating regression models with unknown break points. Statistics in Medecine 22:3055–71.CrossRefGoogle Scholar
and . 2001. Extraterritorial movements of a forest songbird in a fragmented landscape. Conservation Biology 15:729–36.CrossRefGoogle Scholar
(ed.) 2005. The Birds of North America Online. http://bna.birds.cornell.edu.bnaproxy.birds.cornell.edu/BNA/. Ithaca, NY: Cornell Laboratory of Ornithology.
, , , and . 2008. Thresholds in nesting habitat requirements of an old forest specialist, the Brown Creeper (Certhia americana), as conservation targets. Biological Conservation 141:1129–37.CrossRefGoogle Scholar
and . 2004. Thresholds in landscape parameters: occurrence of the white-browed treecreeper Climacteris affinis in Victoria, Australia. Biological Conservation 117:375–91.CrossRefGoogle Scholar
, and . 2002. Effects of forest regeneration on songbird movements in a managed forest landscape of Alberta, Canada. Landscape Ecology 17:247–62.CrossRefGoogle Scholar
1997. Biased detection of bird vocalizations affects comparisons of bird abundance among forested habitats. Condor 99:179–90.CrossRefGoogle Scholar
, and . 1996. Habitat barriers to movement of understory birds in fragmented south-temperate rainforest. Auk 113:944–8.CrossRefGoogle Scholar
and . 2003. Piecewise regression: a tool for identifying ecological thresholds. Ecology 84:2034–41.CrossRefGoogle Scholar
and . 2005. The continuing challenges of testing species distribution models. Journal of Applied Ecology 42:720–30.CrossRefGoogle Scholar
, , and . 2001. Toward ecologically scaled landscape indices. American Naturalist 157:24–41.CrossRefGoogle ScholarPubMed
, and . 2005. Implications of current ecological thinking for biodiversity conservation: a review of the salient issues. Ecology and Society 10:15. Available online at www.ecologyandsociety.org/vol10/iss1/art15.CrossRefGoogle Scholar
and . 1995. Critical thresholds in species' responses to landscape structure. Ecology 76:2446–59.CrossRefGoogle Scholar
and . 1999. Extinction thresholds for species in fractal landscapes. Conservation Biology 13:314–26.CrossRefGoogle Scholar
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