Foraging height and landscape context predict the relative abundance of bird species in urban vegetation patches

In Australian urban environments, revegetation and vegetation restoration are increasingly utilized conservation actions. Simple methods that help assess the utility of urban vegetation for bird species will help direct this effort for bird conservation purposes. We therefore examine whether ecologi...

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Published inAustral ecology Vol. 36; no. 8; pp. 944 - 953
Main Authors SHANAHAN, D. F., POSSINGHAM, H. P., MARTIN, T. G.
Format Journal Article
LanguageEnglish
Published Melbourne, Australia Blackwell Publishing Asia 01.12.2011
Blackwell Publishing Ltd
Subjects
a priori model
Abundance
Biodiversity
Birds
canopy
correlation
foraging
foraging behaviour
land restoration
Landscape
landscape ecology
landscapes
Relative abundance
Revegetation
South East Queensland
Urban areas
urban ecology
Urban environments
Vegetation
Woodlands
Australia
Online AccessGet full text
ISSN1442-9985
1442-9993
DOI10.1111/j.1442-9993.2010.02225.x

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Abstract In Australian urban environments, revegetation and vegetation restoration are increasingly utilized conservation actions. Simple methods that help assess the utility of urban vegetation for bird species will help direct this effort for bird conservation purposes. We therefore examine whether ecological principles can be used to predict, a priori, the relative abundance of different bird species in urban vegetation. Our model proposes that a bird species will be in greater abundance where vegetation structure better reflects its foraging height requirements, and this relationship will be moderated by the landscape context of the patch. To quantify and test this model, we created an index to rank existing and revegetated urban vegetation sites in order of greatest expected abundance for each of 30 bird species. We tested this model, alongside two simpler models which consider landscape context and foraging height preferences alone, using bird abundance data from 20 woodland remnants and 20 revegetated sites in Brisbane, Australia. From these bird abundance data, we calculated the relative abundance of each species between the top‐ranking sites and lowest‐ranking sites. The model which incorporated both foraging height requirements and landscape context made predictions that were positively correlated with the data for 77% of species in remnant vegetation and 67% in revegetation. The results varied across species groups; for example, we achieved lower predictive success for canopy foraging species in the less mature revegetation sites. Overall, this model provided a reasonable level of predictive accuracy despite the diversity of factors which can influence species occurrence in urban landscapes. The model is generic and, subject to further testing, can be used to examine the effect of manipulating vegetation structure and landscape context on the abundance of different bird species in urban vegetation. This could provide a cost‐effective tool for directing urban restoration and revegetation efforts.
AbstractList In Australian urban environments, revegetation and vegetation restoration are increasingly utilized conservation actions. Simple methods that help assess the utility of urban vegetation for bird species will help direct this effort for bird conservation purposes. We therefore examine whether ecological principles can be used to predict, a priori, the relative abundance of different bird species in urban vegetation. Our model proposes that a bird species will be in greater abundance where vegetation structure better reflects its foraging height requirements, and this relationship will be moderated by the landscape context of the patch. To quantify and test this model, we created an index to rank existing and revegetated urban vegetation sites in order of greatest expected abundance for each of 30 bird species. We tested this model, alongside two simpler models which consider landscape context and foraging height preferences alone, using bird abundance data from 20 woodland remnants and 20 revegetated sites in Brisbane, Australia. From these bird abundance data, we calculated the relative abundance of each species between the top-ranking sites and lowest-ranking sites. The model which incorporated both foraging height requirements and landscape context made predictions that were positively correlated with the data for 77% of species in remnant vegetation and 67% in revegetation. The results varied across species groups; for example, we achieved lower predictive success for canopy foraging species in the less mature revegetation sites. Overall, this model provided a reasonable level of predictive accuracy despite the diversity of factors which can influence species occurrence in urban landscapes. The model is generic and, subject to further testing, can be used to examine the effect of manipulating vegetation structure and landscape context on the abundance of different bird species in urban vegetation. This could provide a cost-effective tool for directing urban restoration and revegetation efforts.
Abstract In Australian urban environments, revegetation and vegetation restoration are increasingly utilized conservation actions. Simple methods that help assess the utility of urban vegetation for bird species will help direct this effort for bird conservation purposes. We therefore examine whether ecological principles can be used to predict, a priori, the relative abundance of different bird species in urban vegetation. Our model proposes that a bird species will be in greater abundance where vegetation structure better reflects its foraging height requirements, and this relationship will be moderated by the landscape context of the patch. To quantify and test this model, we created an index to rank existing and revegetated urban vegetation sites in order of greatest expected abundance for each of 30 bird species. We tested this model, alongside two simpler models which consider landscape context and foraging height preferences alone, using bird abundance data from 20 woodland remnants and 20 revegetated sites in Brisbane, Australia. From these bird abundance data, we calculated the relative abundance of each species between the top-ranking sites and lowest-ranking sites. The model which incorporated both foraging height requirements and landscape context made predictions that were positively correlated with the data for 77% of species in remnant vegetation and 67% in revegetation. The results varied across species groups; for example, we achieved lower predictive success for canopy foraging species in the less mature revegetation sites. Overall, this model provided a reasonable level of predictive accuracy despite the diversity of factors which can influence species occurrence in urban landscapes. The model is generic and, subject to further testing, can be used to examine the effect of manipulating vegetation structure and landscape context on the abundance of different bird species in urban vegetation. This could provide a cost-effective tool for directing urban restoration and revegetation efforts.
Author POSSINGHAM, H. P.
MARTIN, T. G.
SHANAHAN, D. F.
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References_xml – reference: Cavailhes J. & Wavresky P. (2003) Urban influences on periurban farmland prices. Eur. Rev. Agric. Econ. 30, 333-57.
– reference: Luther D., Hilty J., Weiss J., Cornwall C., Wipf M. & Ballard G. (2008) Assessing the impact of local habitat variables and landscape context on riparian birds in agricultural, urbanized, and native landscapes. Biodivers. Conserv. 17, 1923-35.
– reference: Morimoto T., Katoh K., Yamaura Y. & Watanabe S. (2006) Can surrounding land cover influence the avifauna in urban/suburban woodlands in Japan? Landsc. Urban Plan. 75, 143-54.
– reference: Vesk P. A., Nolan R., Thomson J. R., Dorrough J. W. & Mac Nally R. (2008) Time lags in provision of habitat resources through revegetation. Biol. Conserv. 141, 174-86.
– reference: Fernandez-Juricic E. (2000) Local and regional effects of pedestrians on forest birds in a fragmented landscape. Condor 102, 247-55.
– reference: Christidis L. & Boles W. E. (2008) Systematics and Taxonomy of Australian Birds. CSIRO Publishing, Collingwood, Victoria.
– reference: de Vries S., Verheij R. A., Groenewegen P. P. & Spreeuwenberg P. (2003) Natural environments-healthy environments? An exploratory analysis of the relationship between greenspace and health. Environ. Plan. 35, 1717-31.
– reference: Brisbane City Council (2009) 2 Million Trees Project. Brisbane City Council, Brisbane.
– reference: Willson M. F. (1974) Avian community organization and habitat structure. Ecology 55, 1017-29.
– reference: McAlpine C. A., Fensham R. J. & Temple-Smith D. E. (2002) Biodiversity conservation and vegetation clearing in Queensland: principles and thresholds. Rangeland J. 24, 36-55.
– reference: Sekercioglu C. H., Ehrlich P. R., Daily G. C., Aygen D., Goehring D. & Sandi R. F. (2002) Disappearance of insectivorous birds from tropical forest fragments. Proc. Natl. Acad. Sci. USA 99, 263-7.
– reference: Jim C. Y. & Chen W. Y. (2006) Perception and attitude of residents toward urban green spaces in Guangzhou (China). Environ. Manage. 38, 338-49.
– reference: Hanski I. (1994) Patch-occupancy dynamics in fragmented landscapes. Trends Ecol. Evol. 9, 131-5.
– reference: Martin T. G. & Possingham H. P. (2005) Predicting the impact of livestock grazing on birds using foraging height data. J. Appl. Ecol. 42, 400-8.
– reference: Brisbane City Council (2004) Regional Ecosystem Mapping V1.0. Brisbane City Council, Brisbane.
– reference: Sims V., Evans K. L., Newson S. E., Tratalos J. A. & Gaston K. J. (2008) Avian assemblage structure and domestic cat densities in urban environments. Divers. Distrib. 14, 387-99.
– reference: Fuller R. A., Irvine K. N., Devine-Wright P., Warren P. H. & Gaston K. J. (2007) Psychological benefits of greenspace increase with biodiversity. Biol. Lett. 3, 390-4.
– reference: Gillies C. S. & Clair C. C. S. (2008) Riparian corridors enhance movement of a forest specialist bird in fragmented tropical forest. Proc. Natl. Acad. Sci. USA 105, 19774-9.
– reference: Barrett G., Silcocks A., Barry S., Cunningham R. & Poulter R. (2003) The New Atlas of Australian Birds. Royal Australasian Ornithologists' Union, Victoria.
– reference: Tratalos J., Fuller R. A., Evans K. L. et al. (2007) Bird densities are asociated with household densities. Glob. Chang. Biol. 13, 1685-95.
– reference: Belisle M. (2005) Measuring landscape connectivity: the challenge of behavioral landscape ecology. Ecology 86, 1988-95.
– reference: Longcore T. & Rich C. (2004) Ecological light pollution. Front. Ecol. Environ. 2, 191-8.
– reference: Higgins P. J., Peter J. M. & Steele W. K., eds (2001) Handbook of Australian, New Zealand and Antarctic Birds. Volume 5: Tyrant-Flycatchers to Chats. Oxford University Press, Melbourne.
– reference: Mac Nally R. (2002) Multiple regression and inference in ecology and conservation biology: further comments on retention of independent variables. Biodivers. Conserv. 11, 1397-401.
– reference: Higgins P. J. & Peter J. M., eds (2002) Handbook of Australian, New Zealand and Antarctic Birds. Volume 6: Pardalotes to Shrike-Thrushes. Oxford University Press, Melbourne.
– reference: Higgins P. J., Peter J. M. & Cowling S. J., eds (2006) Handbook of Australian, New Zealand and Antarctic Birds. Volume 7: Boatbill to Starlings. Oxford University Press, Melbourne.
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Snippet In Australian urban environments, revegetation and vegetation restoration are increasingly utilized conservation actions. Simple methods that help assess the...
Abstract In Australian urban environments, revegetation and vegetation restoration are increasingly utilized conservation actions. Simple methods that help...
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SubjectTerms a priori model
Abundance
Biodiversity
Birds
canopy
correlation
foraging
foraging behaviour
land restoration
Landscape
landscape ecology
landscapes
Relative abundance
Revegetation
South East Queensland
Urban areas
urban ecology
Urban environments
Vegetation
Woodlands
Title Foraging height and landscape context predict the relative abundance of bird species in urban vegetation patches
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Volume 36
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