| scholarly article | Q13442814 |
| P356 | DOI | 10.1111/J.1365-2486.2011.02614.X |
| P50 | author | Barry W. Brook | Q809013 |
| Jane Elith | Q17517062 | ||
| David A. Keith | Q21516502 | ||
| Miguel Bastos Araújo | Q37373516 | ||
| John W Morgan | Q99249395 | ||
| Richard G. Pearson | Q112162721 | ||
| Tracey J. Regan | Q113481598 | ||
| Damien A Fordham | Q56385788 | ||
| Tony D Auld | Q83876892 | ||
| Brendan A Wintle | Q87427518 | ||
| H Resit Akçakaya | Q88172353 | ||
| Colin Yates | Q92187901 | ||
| P2093 | author name string | Matthew White | |
| Camille Mellin | |||
| Michael J. Watts | |||
| Mark Tozer | |||
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| Do pseudo-absence selection strategies influence species distribution models and their predictions? An information-theoretic approach based on simulated data | Q33434929 | ||
| Selecting global climate models for regional climate change studies | Q33445486 | ||
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| P433 | issue | 4 | |
| P921 | main subject | climate change | Q7942 |
| climate change | Q125928 | ||
| extinction risk | Q28610066 | ||
| range shift | Q115532199 | ||
| P6104 | maintained by WikiProject | WikiProject Invasion Biology | Q56241615 |
| P1104 | number of pages | 15 | |
| P304 | page(s) | 1357-1371 | |
| P577 | publication date | 2012-01-25 | |
| P1433 | published in | Global Change Biology | Q1531580 |
| P1476 | title | Plant extinction risk under climate change: are forecast range shifts alone a good indicator of species vulnerability to global warming? | |
| P478 | volume | 18 |
| Q34785510 | A Global Trend towards the Loss of Evolutionarily Unique Species in Mangrove Ecosystems. |
| Q24577138 | Accelerating extinction risk from climate change |
| Q26779539 | Advances in global sensitivity analyses of demographic-based species distribution models to address uncertainties in dynamic landscapes |
| Q35192518 | Better forecasts of range dynamics using genetic data |
| Q57021089 | Chasing a moving target: projecting climate change-induced shifts in non-equilibrial tree species distributions |
| Q31109492 | Climate change may threaten habitat suitability of threatened plant species within Chinese nature reserves |
| Q28657990 | Climate predictions accelerate decline for threatened macrozamia cycads from queensland, australia |
| Q41618123 | Combining dispersal, landscape connectivity and habitat suitability to assess climate-induced changes in the distribution of Cunningham’s skink, Egernia cunninghami |
| Q90724181 | Community science validates climate suitability projections from ecological niche modeling |
| Q57018477 | Conservation management and sustainable harvest quotas are sensitive to choice of climate modelling approach for two marine gastropods |
| Q30720131 | Demographic consequences of climate change and land cover help explain a history of extirpations and range contraction in a declining snake species |
| Q30753798 | Detecting extinction risk from climate change by IUCN Red List criteria |
| Q36342853 | Dispersal and extrapolation on the accuracy of temporal predictions from distribution models for the Darwin's frog. |
| Q47715828 | Distributional dynamics of a vulnerable species in response to past and future climate change: a window for conservation prospects |
| Q57018425 | Diversity patterns of seasonal wetland plant communities mainly driven by rare terrestrial species |
| Q35114164 | Does probability of occurrence relate to population dynamics? |
| Q56983967 | Dominant Drivers of Seedling Establishment in a Fire-Dependent Obligate Seeder: Climate or Fire Regimes? |
| Q30602393 | Evidence of current impact of climate change on life: a walk from genes to the biosphere |
| Q63628177 | Extinction risks of a Mediterranean neo-endemism complex of mountain vipers triggered by climate change |
| Q30827558 | Fine-grain modeling of species' response to climate change: holdouts, stepping-stones, and microrefugia |
| Q31035911 | Geographic variation in climate as a proxy for climate change: Forecasting evolutionary trajectories from species differentiation and genetic correlations |
| Q26776502 | Hot topics in biodiversity and climate change research |
| Q30862906 | How climate, migration ability and habitat fragmentation affect the projected future distribution of European beech |
| Q46258663 | How complex should models be? Comparing correlative and mechanistic range dynamics models. |
| Q100727552 | Identifying island safe havens to prevent the extinction of the World's largest lizard from global warming |
| Q57054746 | Impacts of past habitat loss and future climate change on the range dynamics of South African Proteaceae |
| Q39421604 | Implications of different population model structures for management of threatened plants |
| Q30824931 | Incorporating spatial autocorrelation into species distribution models alters forecasts of climate-mediated range shifts. |
| Q56959973 | Life history and spatial traits predict extinction risk due to climate change |
| Q56451442 | Linking spatially explicit species distribution and population models to plan for the persistence of plant species under global change |
| Q31011298 | Live Fast, Die Young: Experimental Evidence of Population Extinction Risk due to Climate Change. |
| Q30750096 | Managed relocation as an adaptation strategy for mitigating climate change threats to the persistence of an endangered lizard. |
| Q57018520 | Managing the long-term persistence of a rare cockatoo under climate change |
| Q56444108 | Mechanistic modelling of animal dispersal offers new insights into range expansion dynamics across fragmented landscapes |
| Q112594030 | Modeling the potential distribution of Valeriana carnosa Sm. in Argentinean Patagonia: A proposal for conservation and in situ cultivation considering climate change projections |
| Q35580132 | Modelling both dominance and species distribution provides a more complete picture of changes to mangrove ecosystems under climate change |
| Q31002589 | Plant fitness in a rapidly changing world |
| Q30658721 | Population dynamics can be more important than physiological limits for determining range shifts under climate change. |
| Q30867093 | Population viability of Pediocactus bradyi (Cactaceae) in a changing climate |
| Q107468673 | Potential changes in the distribution of Delphinium bolosii and related taxa of the series Fissa from the Iberian Peninsula under future climate change scenarios |
| Q104073593 | Predicted climate change will increase the truffle cultivation potential in central Europe |
| Q56519055 | Predicting persistence in a changing climate: flow direction and limitations to redistribution |
| Q30389858 | Predicting species distributions for conservation decisions |
| Q36341864 | Prediction of the potential geographic distribution of the ectomycorrhizal mushroom Tricholoma matsutake under multiple climate change scenarios |
| Q51445298 | Predictors of contraction and expansion of area of occupancy for British birds. |
| Q92615276 | Range-expansion effects on the belowground plant microbiome |
| Q57018465 | Rapid deforestation threatens mid-elevational endemic birds but climate change is most important at higher elevations |
| Q92502174 | Safety margins and adaptive capacity of vegetation to climate change |
| Q57018492 | Scale dependency of metapopulation models used to predict climate change impacts on small mammals |
| Q56950709 | Shallow environmental gradients put inland species at risk: Insights and implications from predicting future distributions ofEucalyptusspecies in South Western Australia |
| Q30620992 | Space, time and complexity in plant dispersal ecology |
| Q31034450 | Spatio-temporal variation of biotic factors underpins contemporary range dynamics of congeners. |
| Q58651060 | Species distribution modelling using bioclimatic variables to determine the impacts of a changing climate on the western ringtail possum (Pseudocheirus occidentals; Pseudocheiridae) |
| Q51480048 | Strong but opposing β-diversity-stability relationships in coral reef fish communities. |
| Q56964084 | Synthesis of ecosystem vulnerability to climate change in the Netherlands shows the need to consider environmental fluctuations in adaptation measures |
| Q58241711 | The Climate Adaptation Frontier |
| Q57584698 | The Importance of Assessing Climate Change Vulnerability to Address Species Conservation |
| Q30844782 | The effects of climate change and land-use change on demographic rates and population viability. |
| Q57018470 | The influence of non-climate predictors at local and landscape resolutions depends on the autecology of the species |
| Q28659914 | The trajectory of dispersal research in conservation biology. Systematic review |
| Q57018494 | Tools for integrating range change, extinction risk and climate change information into conservation management |
| Q35662060 | Towards a more holistic research approach to plant conservation: the case of rare plants on oceanic islands |
| Q56755131 | Traits to stay, traits to move: a review of functional traits to assess sensitivity and adaptive capacity of temperate and boreal trees to climate change |
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| Q35865186 | Variation at the DRD4 locus is associated with wariness and local site selection in urban black swans |
| Q30855686 | Warning times for species extinctions due to climate change |
| Q56985716 | Whose backyard? Some precautions in choosing recipient sites for assisted colonisation of Australian plants and animals |
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