Impact of a prolonged decline in rainfall on eucalypt woodlands in southwestern Australia and its consequences for avifauna
A. Sara Angel A * and J. Stuart Bradley AA School of Veterinary and Life Science, Murdoch University, South Street Campus, Murdoch, WA, Australia.
Pacific Conservation Biology 28(6) 491-504 https://doi.org/10.1071/PC20078
Submitted: 30 March 2021 Accepted: 3 September 2021 Published: 18 October 2021
© 2022 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)
Abstract
Aims: Our objective was to establish a relationship between long-term variation in the climatic environment, tree canopy decline and observed effects on the population dynamics of avifauna in the Dryandra Woodlands in southwestern Australia. These geographically isolated remnant woodlands are rich in endemic species and sustain a diverse range of ecological communities, but are threatened by habitat degradation and a decline in rainfall.
Methods: We used annual rainfall data, averaged from a series of weather stations within 100 km of the Dryandra Woodlands and a time series analysis to investigate long-term changes in annual rainfall. Satellite spectral observations of eight study sites at Dryandra was used to measure changes in Projected Foliage Cover (PFC) of old growth Eucalyptus wandoo at all sites. Our mist-net trapping study across three years and all eight sites, targeted two focal species; the rufous treecreeper (Climacteris rufa) and yellow-plumed honeyeater (Ptilotula ornata). We investigated the relationship between the captures of each species and variation in PFC, between sites and across years. Also in a separate demographic study, capture-mark-recapture data was used to estimate the apparent survival rate of each species, following the robust design for open and closed populations.
Key results: We demonstrate a long-term and continuing decline in average annual rainfall that is accelerating. We found the rainfall trend is concomitant with a long-term decline in PFC of E. wandoo and that the previous year’s annual rainfall is a predictor of average PFC across all sites. Additionally, we discovered that the PFC at each site, in each year, is a predictor of the number of yellow-plumed honeyeaters which prefer feeding on canopy insects and not a predictor of the predominantly ground-foraging rufous treecreeper. We also found a substantial difference in the apparent survival rates between the two species, with the apparent survival of yellow-plumed honeyeaters being approximately half that of rufous treecreepers. This difference was partially attributed to the likely movement outside of the study area due to decreasing habitat quality.
Conclusions and implications: Overall, our results do suggest that some impacts of long-term rainfall trends can be traced to particular species through PFC variation, but the response between species to habitat change will differ and depend on species-specific habitat requirements. As increasing greenhouse emissions are associated with declining rainfall in southwestern Australia, this study shows if rainfall decline and habitat degradation continue, it will have catastrophic consequences for woodland ecosystems.
Keywords: bird ecology, canopy, climate change, climate modelling, ecosystem change, extreme climate events, Eucalyptus spp., Eucalyptus wandoo, rufus treecreeper, yellow-plumed honeyeater.
References
ABBBS (2021) ‘Australian Bird and Bat Banding Scheme’. (Australian Government Department of Environment: Canberra, ACT, Australia). Available at https://www.environment.gov.au/science/bird-and-bat-banding/banding-data/search-abbbs-database [Accessed 7 August 2021].Aitken, SN, and Whitlock, MC (2013). Assisted gene flow to facilitate local adaptation to climate change. Annual Review of Ecology, Evolution, and Systematics 44, 367–388.
| Assisted gene flow to facilitate local adaptation to climate change.Crossref | GoogleScholarGoogle Scholar |
Angel AS (2015) Landscape genetics and effects of climate change on the population viability of declining avifauna in the fragmented eucalypt woodlands of the West Australian wheatbelt. PhD thesis, Murdoch University, Perth, WA, Australia.
Austin MP (2002) Case studies of the use of environmental gradients in vegetation and fauna modelling: theory and practice in Australia and New Zealand. In ‘Predicting species occurrences issues of accuracy and scale’. (Eds JM Scott, PJ Heglund, ML Morrison) pp. 73–82. (Island Press: London, UK)
Barbeta, A, Mejía-Chang, M, Ogaya, R, Voltas, J, Dawson, TE, and Peñuelas, J (2015). The combined effects of a long-term experimental drought and an extreme drought on the use of plant-water sources in a Mediterranean forest. Global Change Biology 21, 1213–1225.
| The combined effects of a long-term experimental drought and an extreme drought on the use of plant-water sources in a Mediterranean forest.Crossref | GoogleScholarGoogle Scholar | 25359123PubMed |
Batini, F (2004). Comparison of changes to water levels in Deep bores 1975–2004 – Helena Catchment, Western Australia. Western Wildlife 8, 4.
Bergengren, JC, Waliser, DE, and Yung, YL (2011). Ecological sensitivity: a biospheric view of climate change. Climatic Change 107, 3–4.
| Ecological sensitivity: a biospheric view of climate change.Crossref | GoogleScholarGoogle Scholar |
BOM (2016 [2015]) Australian Government Bureau of Meteorology. Available at http://www.bom.gov.au/climate/data/index.shtml [Accessed 2015 and 2016].
Bradshaw, CJA (2012). Little left to lose: deforestation and forest degradation in Australia since European colonization. Journal of Plant Ecology 5, 109–120.
| Little left to lose: deforestation and forest degradation in Australia since European colonization.Crossref | GoogleScholarGoogle Scholar |
Brooker L, Atkins L, Ingram J (2001) Enhancing biodiversity values in agricultural lands morbinning sub-catchment and surrounds August 2001. A CSIRO report commissioned by Greening Australia, Western Australia.
Brooker, LC, and Brooker, MG (2002). Dispersal and population dynamics of the blue-breasted fairy-wren, Malurus pulcherrimus, in fragmented habitat in the Western Australian wheatbelt. Wildlife Research 29, 225–233.
| Dispersal and population dynamics of the blue-breasted fairy-wren, Malurus pulcherrimus, in fragmented habitat in the Western Australian wheatbelt.Crossref | GoogleScholarGoogle Scholar |
Brouwers, NC, Mercer, J, Lyons, T, Poot, P, Veneklaas, E, and Hardy, G (2013). Climate and landscape drivers of tee decline in a Mediterranean ecoregion. Ecology and Evolution 3, 67–79.
| Climate and landscape drivers of tee decline in a Mediterranean ecoregion.Crossref | GoogleScholarGoogle Scholar |
Cai, W, Borlace, S, Lengaigne, M, van Rensch, P, Collins, M, Vecchi, G, Timmermann, A, Santoso, A, McPhaden, M, Wu, L, England, MH, Wang, G, Guilyardi, E, and Jin, F-F (2014). Increasing frequency of extreme El Niño events due to greenhouse warming. Nature Climate Change 4, 111–116.
| Increasing frequency of extreme El Niño events due to greenhouse warming.Crossref | GoogleScholarGoogle Scholar |
CALM (1995) Dryandra Woodland Management Plan 1995–2005 – management plan no. 30. Department of Conservation and Land Management, National Parks and Nature Conservation and Lands and Forests Commission, Perth, WA, Australia.
Chambers, LE, Hughes, L, and Weston, MA (2005). Climate change and its impact on Australia’s avifauna. Emu – Austral Ornithology 105, 1–20.
| Climate change and its impact on Australia’s avifauna.Crossref | GoogleScholarGoogle Scholar |
Close, DC, and Davidson, NJ (2004). Review of rural tree decline in a changing Australian climate. Tasforests , 1–18.
Coates A (1993) Vegetation survey of Dryandra forest. Prepared for the Department of Conservation and Land Management, Perth Western Australia.
CSIRO (2005) Ryan, B., Smith, I. and Bates, B., Indian Ocean Climate Initiative (IOCI): how will the future climate of south-western Australia be affected by the greenhouse signature? A presentation given in Melbourne, 17th November 2005. CSIRO Marine and Atmospheric Research, Clayton, Vic., Australia.
CSIRO (2015) Climate change in Australia-projection for Australia’s NRM regions. Climate change in Australia technical report. (CSIRO and Bureau of Meteorology: Clayton, Vic., Australia) Available at https://www.climatechangeinaustralia.gov.au/media/ccia/2.2/cms_page_media/168/CCIA_2015_NRM_TR_Chapter%203.pdf
Dalmaris E (2012) Eucalyptus wandoo: tolerance to drought and salinity in relation to provenance and evolutionary history in southwestern Australia. PhD thesis, University of Western Australia, Perth, WA, Australia.
DBCA (2021) ‘Wandoo woodlands.’ (The Department of Biodiversity Conservation and Attractions) Available at https://library.dbca.wa.gov.au/static/FullTextFiles/019398 [Accessed 12 January 2021].
Diggle PJ (1990) ‘Time series: a biostatistical introduction.’ (Oxford University Press: Oxford, UK)
Doerr, VAJ, Doerr, ED, and Davies, MJ (2011). Dispersal behaviour of Brown Treecreeper predicts functional connectivity for several other woodland birds. Emu – Austral Ornithology 111, 71–83.
| Dispersal behaviour of Brown Treecreeper predicts functional connectivity for several other woodland birds.Crossref | GoogleScholarGoogle Scholar |
Fitzpatrick, MC, Gove, AD, Saunders, NJ, and Dunn, RR (2008). Climate change, plant migration, and range collapse in a global biodiversity hotspot: the Banksia (Proteaceae) of Western Australia. Global Change Biology 14, 1337–1352.
| Climate change, plant migration, and range collapse in a global biodiversity hotspot: the Banksia (Proteaceae) of Western Australia.Crossref | GoogleScholarGoogle Scholar |
Ford, HA (2011). The causes of decline of birds of eucalypt woodlands: advances in our knowledge over the last 10 years. Emu – Austral Ornithology 111, 1–9.
| The causes of decline of birds of eucalypt woodlands: advances in our knowledge over the last 10 years.Crossref | GoogleScholarGoogle Scholar |
Ford, HA, Barrett, GW, Saunders, DA, and Recher, HF (2001). Why have birds in the woodlands of Southern Australia declined? Biological Conservation 97, 71–88.
| Why have birds in the woodlands of Southern Australia declined?Crossref | GoogleScholarGoogle Scholar |
Garkaklis M, Behn G (2009) Assessment of Eucalyptus wandoo (Wandoo) and other tree canopy decline using Landsat Trend Analysis. (Report to Department of Environment and Conservation: WA, Australia)
Harvey J, Keighery G (2012) Wheatbelt Baselining Project. Benchmarking wheatbelt vegetation. Classification and description of eucalypt woodlands. (Report by the Department of Environment and Conservation: Perth, WA, Australia) Available at https://www.dpaw.wa.gov.au/images/about/science/wheatbelt_woodland_communities_report.pdf [Accessed 15 March 2021].
Hobbs RJ (2002) Chapter 3: The ecological context: a landscape perspective. In ‘Handbook of ecological restoration volume one-principles of restoration’. (Eds MR Perrow, AJ Davy) pp. 24–45. (Cambridge University Press: Cambridge, UK)
Hoffmann, AA, Rymer, PD, Byrne, M, Ruthrof, KX, Whinam, J, McGeoch, M, Bergstrom, DM, Guerin, GR, Sparrow, B, Joseph, L, Hill, SJ, Andrew, NR, Camac, J, Bell, N, Riegler, M, Gardner, JL, and Williams, SE (2019). Impacts of recent climate change on terrestrial flora and fauna: some emerging Australian examples. Austral Ecology 44, 3–27.
| Impacts of recent climate change on terrestrial flora and fauna: some emerging Australian examples.Crossref | GoogleScholarGoogle Scholar |
Hughes, JD, Petrone, KC, and Silberstein, RP (2012). Drought, groundwater storage and stream flow decline in southwestern Australia. Geophysical Research Letters 39, L03408.
| Drought, groundwater storage and stream flow decline in southwestern Australia.Crossref | GoogleScholarGoogle Scholar |
IOCI (2002) ‘Living with climate change – an overview of potential climate change impacts on Australia.’ (Australian Department of the Environment & Heritage, Australian Greenhouse Office) Available at http://www.greenhouse.gov.au [Accessed 4 September 2009].
IPCC (2007) Inter-Governmental Panel on Climate Change Fourth Assessment Report, Working Group II Report ‘Impacts, Adaptation and Vulnerability’. Available at www.ipcc.ch/pccreports/ar4-wg2.htm [Accessed 28 November 2007].
IPCC (2014) Inter-Governmental Panel on Climate Change Fifth Assessment Report, Working Group I ‘The Physical Science Basis’. Available at http://www.climatechange.gov.au/climate-change/climate-science/intergovernmental-panel-climate-change [Accessed 7 August 2014].
Lambeck, RJ (1997). Focal species: a multi-species umbrella for nature conservation. Conservation Biology 11, 849–856.
| Focal species: a multi-species umbrella for nature conservation.Crossref | GoogleScholarGoogle Scholar |
Leibold MA, Miller TE (2004) From metapopulations to metacommunities. In ‘Ecology, genetics, and evolution of metapopulations’. (Eds I Hanski, OE Gaggiotti) pp. 133–150. (Elsevier Academic Press: London, UK)
Lindenmayer, DB, Lane, P, Crane, M, Florance, D, Foster, CN, Ikin, K, Michael, D, Sato, CF, Scheele, BC, and Westgate, M (2019). Weather effects on birds of different size are mediated by long-term climate and vegetation type in endangered temperate woodlands. Global Change Biology 25, 675–685.
| Weather effects on birds of different size are mediated by long-term climate and vegetation type in endangered temperate woodlands.Crossref | GoogleScholarGoogle Scholar | 30431211PubMed |
Liu, D, Ogaya, R, Barbeta, A, Yang, X, and Peñuelas, J (2018). Long-term experimental drought combined with natural extremes accelerate vegetation shift in a Mediterranean holm oak forest. Environmental and Experimental Botany 151, 1–11.
| Long-term experimental drought combined with natural extremes accelerate vegetation shift in a Mediterranean holm oak forest.Crossref | GoogleScholarGoogle Scholar |
Luck G (1996) Bird population responses and artificial nest predation at inherent and induced edges in the Murray Mallee, South Australia. Honours thesis, University of Adelaide, Adelaide, SA, Australia.
Luck, G, Charmantier, A, and Ezanno, P (2001). Seasonal and landscape differences in the foraging behaviour of the Rufous Treecreeper Climacteris rufa. Pacific Conservation Biology 7, 9–20.
| Seasonal and landscape differences in the foraging behaviour of the Rufous Treecreeper Climacteris rufa.Crossref | GoogleScholarGoogle Scholar |
Luck GW (2000) Landscape differences in the ecology of the Rufous Treecreeper Climacteris rufa. PhD thesis, Edith Cowan University, Perth, WA, Australia.
Luck, GW (2002). The habitat requirements of the Rufous Treecreeper (Climacteris rufa). 1. Preferential habitat use demonstrated at multiple spatial scales. Biological Conservation 105, 383–394.
| The habitat requirements of the Rufous Treecreeper (Climacteris rufa). 1. Preferential habitat use demonstrated at multiple spatial scales.Crossref | GoogleScholarGoogle Scholar |
Matusick, G, Ruthoff, KX, Kala, J, Brouwers, NC, Breshears, DD, and Hardy, GJ (2018). Chronic historical drought legacy exacerbates tree mortality and crown dieback during acute heatwave-compounded drought. Environmental Research Letters 13, 095002.
| Chronic historical drought legacy exacerbates tree mortality and crown dieback during acute heatwave-compounded drought.Crossref | GoogleScholarGoogle Scholar |
Matusick, G, Ruthroff, KX, Brouwers, NC, Dell, B, and Hardy, GJ (2013). Sudden forest canopy collapse corresponding with extreme drought and heat in a Mediterranean-type eucalypt forest in southwestern Australia. European Journal of Forest Research 132, 497–510.
| Sudden forest canopy collapse corresponding with extreme drought and heat in a Mediterranean-type eucalypt forest in southwestern Australia.Crossref | GoogleScholarGoogle Scholar |
Mercer JW (2003) Survey of Eucalyptus wandoo decline. Report prepared for CALM Science Division, Como, Western Australia, Australia.
Mercer JW (2008) Second survey of Eucalyptus wandoo decline. Final report on wandoo decline on behalf of the Wandoo Recovery Group. (Department of the Environment and Conservation and WWF-Australia)
Mettke-Hofmann, C (2017). Avian movements in a modern world: cognitive challenges. Animal Cognition 20, 77–86.
| Avian movements in a modern world: cognitive challenges.Crossref | GoogleScholarGoogle Scholar | 27287625PubMed |
Mitchell, PJ, O’Grady, AP, Hayes, KR, and Pinkard, EA (2014). Exposure of trees to drought-induced die-off is defined by a common climatic threshold across different vegetation types. Ecology and Evolution 4, 1088–1101.
| Exposure of trees to drought-induced die-off is defined by a common climatic threshold across different vegetation types.Crossref | GoogleScholarGoogle Scholar | 24772285PubMed |
Myers, N, Mittermeier, RA, Mittermeier, CG, da Fonseca, GAB, and Kent, J (2000). Biodiversity hotspots for conservation priorities. Nature 403, 853–858.
| Biodiversity hotspots for conservation priorities.Crossref | GoogleScholarGoogle Scholar | 10706275PubMed |
Nolan, C, Overpeck, JT, Allen, JRM, Anderson, PM, Betancourt, JL, Binney, HL, Brewer, S, Bush, MB, Chase, BM, Cheddadi, R, Djamali, M, Dodson, J, Edwards, ME, Gosling, WD, Haberle, S, Hotchkiss, SC, Huntley, B, Ivory, SJ, Kershaw, AP, Kim, SH, Latorre, C, Leydet, M, Lézine, A, Liu, KB, Liu, Y, Lozhkin, AV, McGlone, MS, Marchant, RA, Momohara, A, Moreno, PI, Müller, S, Otto-Bliesner, BL, Shen, C, Stevenson, J, Takahara, H, Tarasov, PE, Tipton, J, Vincens, A, Weng, C, Xu, Q, Zheng, Z, and Jackson, ST (2018). Past and future global transformation of terrestrial ecosystems under climate change. Science 361, 920–923.
| Past and future global transformation of terrestrial ecosystems under climate change.Crossref | GoogleScholarGoogle Scholar | 30166491PubMed |
Nyári, ÁS, and Joseph, L (2011). Systematic dismantlement of Lichenostomus improves the basis for understanding relationships within the honeyeaters (Meliphagidae) and the historical development of Australo-Papuan bird communities. Emu – Austral Ornithology 111, 202–211.
| Systematic dismantlement of Lichenostomus improves the basis for understanding relationships within the honeyeaters (Meliphagidae) and the historical development of Australo-Papuan bird communities.Crossref | GoogleScholarGoogle Scholar |
Pollock, KH, and Raveling, DG (1982). Assumptions of modern band-recovery models, with emphasis on heterogeneous survival rates. The Journal of Wildlife Management 46, 88–98.
| Assumptions of modern band-recovery models, with emphasis on heterogeneous survival rates.Crossref | GoogleScholarGoogle Scholar |
Prober, SM, Byrne, M, McLean, EH, Steane, DA, Potts, BM, Vaillancourt, RE, and Stock, WD (2015). Climate adjusted provenancing: a strategy forclimate-resilient ecological restoration. Frontiers in Ecology and Evolution 3, 65.
| Climate adjusted provenancing: a strategy forclimate-resilient ecological restoration.Crossref | GoogleScholarGoogle Scholar |
Recher, HF, and Davis, WE (1998). The foraging profile of a wandoo woodland avifauna in early spring. Australian Journal of Ecology 23, 514–527.
| The foraging profile of a wandoo woodland avifauna in early spring.Crossref | GoogleScholarGoogle Scholar |
Risbey, JS, Pook, MJ, McIntosh, PC, Wheeler, MC, and Hendon, HH (2009). On the remote drivers of rainfall variability in Australia. Monthly Weather Review 137, 3233–3253.
| On the remote drivers of rainfall variability in Australia.Crossref | GoogleScholarGoogle Scholar |
Rose PW (1993) Production of habitat hollows by wheatbelt Eucalyptus. Final report – project R053. (Department of Conservation and Land Management (CALM): Perth, WA, Australia)
Rowley I, Russell E (1991) Demography of passerines in the temperate Southern Hemisphere. In ‘Bird population studies: Relevance to conservation management’. (Eds C Perrins, JD Lebreton, GJM Hirons) pp. 22–44. (Oxford University Press: Oxford, UK)
Saunders DA, Ingram JA (1995) ‘Birds of southwestern Australia.’ (Surrey Beatty & Sons: Chipping Norton, UK)
Saunders, D, Wintle, BA, Mawson, PR, and Dawson, R (2013). Egg-laying and rainfall synchrony in an endangered bird species: implications for conservation in a changing climate. Biological Conservation 161, 1–9.
| Egg-laying and rainfall synchrony in an endangered bird species: implications for conservation in a changing climate.Crossref | GoogleScholarGoogle Scholar |
Saunders, DA (1989). Changes in the avifauna of a region, district and remnant as a result of fragmentation of native vegetation: the wheatbelt of Western Australia. A case study. Biological Conservation 50, 99–135.
| Changes in the avifauna of a region, district and remnant as a result of fragmentation of native vegetation: the wheatbelt of Western Australia. A case study.Crossref | GoogleScholarGoogle Scholar |
Smettem, KRJ, Waring, RH, Callow, JN, Wilson, M, and Mu, Q (2013). Satellite-derived estimates of forest leaf area index in southwest Western Australia are not tightly coupled to interannual variations in rainfall: implications for groundwater decline in a drying climate. Global Change Biology 19, 2401–2412.
| Satellite-derived estimates of forest leaf area index in southwest Western Australia are not tightly coupled to interannual variations in rainfall: implications for groundwater decline in a drying climate.Crossref | GoogleScholarGoogle Scholar |
Southwood TRE, Henderson PA (2000) ‘Ecological methods,’ 3rd edn. (Blackwell Science Ltd, London, UK)
SPSS (2016) IBM Corp. Released 2013. IBM SPSS statistics for Windows (version 22.0). (IBM Corp: Armonk, NY, USA)
SRES (2000) Special report on emissions scenarios, a special report of working group III of the intergovernmental panel on climate change (Cambridge University Press: Cambridge, UK) Available at https://www.ipcc.ch/site/assets/uploads/2018/03/emissions_scenarios-1.pdf
Thomas CD, Hanski I (2004) Metapopulation dynamics in changing environments: butterfly responses to habitat and climate change. In ‘Ecology, genetics and evolution of metapopulations’. (Eds I Hannski, OE Gaggiotti) pp. 489–514. (Elsevier Academic Press: London, UK)
Veneklaas, E, and Manning, L (2007). Wandoo crown decline linked to a changing environment? Landscope 22, 17–22.
Wallace, J, Behn, G, and Furby, S (2006). Vegetation condition assessment and monitoring from sequences of satellite imagery. Ecological Management & Restoration 7, S31–S36.
| Vegetation condition assessment and monitoring from sequences of satellite imagery.Crossref | GoogleScholarGoogle Scholar |
Watson, DM (2011). A productivity-based explanation for woodland bird declines: poorer soils yield less food. Emu – Austral Ornithology 111, 10–18.
| A productivity-based explanation for woodland bird declines: poorer soils yield less food.Crossref | GoogleScholarGoogle Scholar |
White, GC, and Burnham, KP (1999). Program MARK: survival estimation from populations of marked animals. Bird Study 46, S120–S139.
| Program MARK: survival estimation from populations of marked animals.Crossref | GoogleScholarGoogle Scholar |
White GC, Franklin AB, Shenk TM (2002) Estimating parameters of PVA models from data on marked animals. In ‘Population viability analysis’. (Eds SR Beissinger, DR McCullough) pp. 169–190. (The University of Chicago Press: Chicago, IL, USA)
Wigley, TML, Richels, R, and Edmonds, JA (1996). Economic and environmental choices in the stabilization of atmospheric CO2 concentrations. Nature 379, 240–243.
| Economic and environmental choices in the stabilization of atmospheric CO2 concentrations.Crossref | GoogleScholarGoogle Scholar |
Williams BK, Nichols JD, Conroy MJ (2002) Combining closed and open mark-recapture models: the robust design. In ‘Analysis and management of animal populations’. pp. 523–554. (Academic Press)
Wilson K (1997) The foraging ecology and habitat selection of the Yellow-plumed Honeyeater (Lichenostomus omatus) at Dryandra Woodland, Western Australia. PhD thesis, Edith Cowan University, Perth, WA, Australia.
Wilson, K, and Recher, HF (2001). Foraging ecology and habitat selection of the Yellow-plumed Honeyeater, Lichenostomus ornatus, in a Western Australian woodland: implications for conservation. Emu – Austral Ornithology 101, 89–94.
| Foraging ecology and habitat selection of the Yellow-plumed Honeyeater, Lichenostomus ornatus, in a Western Australian woodland: implications for conservation.Crossref | GoogleScholarGoogle Scholar |
Wooller, RD, Richardson, KC, Garavanta, CAM, Saffer, VM, Anthony, C, and Wooller, SJ (1998). The influence of annual rainfall upon capture rates of a nectar-dependent marsupial. Wildlife Research 25, 165–169.
| The influence of annual rainfall upon capture rates of a nectar-dependent marsupial.Crossref | GoogleScholarGoogle Scholar |
Yates, CJ, McNeill, A, Elith, J, and Midgley, GF (2010). Assessing the impacts of climate change and land transformation on Banksia in the South West Australian Floristic Region. Diversity and Distributions 16, 187–201.
| Assessing the impacts of climate change and land transformation on Banksia in the South West Australian Floristic Region.Crossref | GoogleScholarGoogle Scholar |
Zdunic K, Behn G, van Dongen R (2012) Investigating the dynamics of wandoo crown decline with time series Landsat imagery. In ‘International archives of the photogrammetry, remote sensing and spatial information sciences, XXXIX-B3, XXII ISPRS congress, 25 August–1 September 2012, Melbourne, Australia’.