Long-term monitoring reveals the impact of changing climate and habitat on the fitness of cavity-nesting songbirds
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[1] F. Pelletier,et al. Interacting effects of cold snaps, rain, and agriculture on the fledging success of a declining aerial insectivore , 2021, bioRxiv.
[2] Indrajeet Patil,et al. performance: An R Package for Assessment, Comparison and Testing of Statistical Models , 2021, J. Open Source Softw..
[3] J. Gardner,et al. Opportunity costs and the response of birds and mammals to climate warming , 2021 .
[4] B. O. Wolf,et al. Exposure to climate change drives stability or collapse of desert mammal and bird communities , 2021, Science.
[5] A. Engelbrecht,et al. Extreme temperatures compromise male and female fertility in a large desert bird , 2021, Nature Communications.
[6] F. Jiguet,et al. Wintering bird communities are tracking climate change faster than breeding communities. , 2021, The Journal of animal ecology.
[7] R. Arlettaz,et al. Nestling diet and parental food provisioning in a declining mountain passerine reveal high sensitivity to climate change , 2020, Journal of Avian Biology.
[8] D. Saltz,et al. Roads and Road-Posts as an Ecological Trap for Cavity Nesting Desert Birds , 2020, Frontiers in Conservation Science.
[9] D. Winkler,et al. Birds advancing lay dates with warming springs face greater risk of chick mortality , 2020, Proceedings of the National Academy of Sciences.
[10] T. Newbold,et al. Tropical and Mediterranean biodiversity is disproportionately sensitive to land-use and climate change , 2020, Nature Ecology & Evolution.
[11] Erle C. Ellis,et al. Global human influence maps reveal clear opportunities in conserving Earth’s remaining intact terrestrial ecosystems , 2020, Global change biology.
[12] C. Spottiswoode,et al. High temperatures drive offspring mortality in a cooperatively breeding bird , 2020, bioRxiv.
[13] J. Andrew Royle,et al. Migratory behavior and winter geography drive differential range shifts of eastern birds in response to recent climate change , 2020, Proceedings of the National Academy of Sciences.
[14] F. Rego,et al. Extreme events are more likely to affect the breeding success of lesser kestrels than average climate change , 2020, Scientific Reports.
[15] S. Hille,et al. Heavy and persistent rainfall leads to brood reduction and nest failure in a passerine bird , 2020, Journal of Avian Biology.
[16] J. Wiens,et al. Recent responses to climate change reveal the drivers of species extinction and survival , 2020, Proceedings of the National Academy of Sciences.
[17] B. Furnas. Rapid and varied responses of songbirds to climate change in California coniferous forests , 2020 .
[18] T. Newbold,et al. Local climatic changes affect biodiversity responses to land use: A review , 2019, Diversity and Distributions.
[19] A. Jacobson,et al. Global areas of low human impact (‘Low Impact Areas’) and fragmentation of the natural world , 2019, Scientific Reports.
[20] B. Sinervo,et al. Cooling requirements fueled the collapse of a desert bird community from climate change , 2019, Proceedings of the National Academy of Sciences.
[21] W. Sutherland,et al. Responses of global waterbird populations to climate change vary with latitude , 2019, bioRxiv.
[22] A. McKechnie,et al. Chronic, sublethal effects of high temperatures will cause severe declines in southern African arid-zone birds during the 21st century , 2019, Proceedings of the National Academy of Sciences.
[23] Mollie E. Brooks,et al. Statistical modeling of patterns in annual reproductive rates. , 2019, Ecology.
[24] Brett R. Scheffers,et al. Global buffering of temperatures under forest canopies , 2019, Nature Ecology & Evolution.
[25] S. Griffith,et al. High air temperatures induce temporal, spatial and social changes in the foraging behaviour of wild zebra finches , 2019, Animal Behaviour.
[26] Joseph M. Northrup,et al. Synergistic effects of climate and land‐use change influence broad‐scale avian population declines , 2019, Global change biology.
[27] J. Fitzpatrick,et al. Climate change causes upslope shifts and mountaintop extirpations in a tropical bird community , 2018, Proceedings of the National Academy of Sciences.
[28] K. Martin,et al. Nest boxes increase reproductive output for Tree Swallows in a forest grassland matrix in central British Columbia , 2018, PloS one.
[29] C. Lindell,et al. Falcons using orchard nest boxes reduce fruit‐eating bird abundances and provide economic benefits for a fruit‐growing region , 2018 .
[30] Aldina M. A. Franco,et al. Context-dependent conservation of the cavity-nesting European Roller , 2018, Ibis.
[31] Steven R. Beissinger,et al. Collapse of a desert bird community over the past century driven by climate change , 2018, Proceedings of the National Academy of Sciences.
[32] B. Zuckerberg,et al. Effects of temperature and precipitation on grassland bird nesting success as mediated by patch size , 2018, Conservation biology : the journal of the Society for Conservation Biology.
[33] Alex Hall,et al. Increasing precipitation volatility in twenty-first-century California , 2018, Nature Climate Change.
[34] Kristen E. Dybala,et al. Evaluating Riparian Restoration Success: Long-Term Responses of the Breeding Bird Community in California’s Lower Putah Creek Watershed , 2018, Ecological Restoration.
[35] A. Lehikoinen,et al. Stronger response of farmland birds than farmers to climate change leads to the emergence of an ecological trap , 2018 .
[36] Casper W. Berg,et al. glmmTMB Balances Speed and Flexibility Among Packages for Zero-inflated Generalized Linear Mixed Modeling , 2017, R J..
[37] K. Martin,et al. Effects of severe weather on reproduction for sympatric songbirds in an alpine environment: Interactions of climate extremes influence nesting success , 2017, The Auk.
[38] Neil D. Burgess,et al. An Ecoregion-Based Approach to Protecting Half the Terrestrial Realm , 2017, Bioscience.
[39] B. O. Wolf,et al. Mapping evaporative water loss in desert passerines reveals an expanding threat of lethal dehydration , 2017, Proceedings of the National Academy of Sciences.
[40] James E. M. Watson,et al. Biodiversity: The ravages of guns, nets and bulldozers , 2016, Nature.
[41] M. Lambrechts,et al. Experimental demonstration of an ecological trap for a wild bird in a human-transformed environment , 2016, Animal Behaviour.
[42] Arvind O. Panjabi,et al. Extremes of heat, drought and precipitation depress reproductive performance in shortgrass prairie passerines , 2016 .
[43] Marta A. Jarzyna,et al. Synergistic effects of climate and land cover: grassland birds are more vulnerable to climate change , 2016, Landscape Ecology.
[44] J. Dickinson,et al. Habitat quality and nest-box occupancy by five species of oak woodland birds , 2016, The Auk.
[45] T. Pärt,et al. Rainfall during parental care reduces reproductive and survival components of fitness in a passerine bird , 2014, Ecology and evolution.
[46] B. Zuckerberg,et al. Climate change in our backyards: the reshuffling of North America's winter bird communities , 2015, Global change biology.
[47] D. Letourneau,et al. Establishing songbird nest boxes increased avian insectivores and reduced herbivorous arthropods in a Californian vineyard, USA , 2014 .
[48] J. Barber,et al. An experimental investigation into the effects of traffic noise on distributions of birds: avoiding the phantom road , 2013, Proceedings of the Royal Society B: Biological Sciences.
[49] William F. Laurance,et al. Near-Complete Extinction of Native Small Mammal Fauna 25 Years After Forest Fragmentation , 2013, Science.
[50] Stuart K. McFeeters,et al. Using the Normalized Difference Water Index (NDWI) within a Geographic Information System to Detect Swimming Pools for Mosquito Abatement: A Practical Approach , 2013, Remote. Sens..
[51] R. Dunn,et al. Effect of climate change on breeding phenology, clutch size and chick survival of an upland bird , 2013 .
[52] D. Winkler,et al. Temperature effects on food supply and chick mortality in tree swallows (Tachycineta bicolor) , 2013, Oecologia.
[53] F. Jiguet,et al. Differences in the climatic debts of birds and butterflies at a continental scale , 2012 .
[54] Julie A. Jedlicka,et al. Avian Conservation Practices Strengthen Ecosystem Services in California Vineyards , 2011, PloS one.
[55] B. Huntley,et al. Habitat microclimates drive fine‐scale variation in extreme temperatures , 2011 .
[56] Maria Romano,et al. Climate warming, ecological mismatch at arrival and population decline in migratory birds , 2011, Proceedings of the Royal Society B: Biological Sciences.
[57] B. Kendall,et al. A Stochastic Model for Annual Reproductive Success , 2010, The American Naturalist.
[58] M. Whittingham,et al. Impacts of climate on prey abundance account for fluctuations in a population of a northern wader at the southern edge of its range , 2010 .
[59] T. Pärt,et al. Habitat-specific differences in adult survival rates and its links to parental workload and on-nest predation. , 2010, The Journal of animal ecology.
[60] Anders Pape Møller,et al. Populations of migratory bird species that did not show a phenological response to climate change are declining , 2008, Proceedings of the National Academy of Sciences.
[61] J. P. Mccarty,et al. Relative importance off environmental variables in determining the growth off nestling Tree Swallows Tachycineta bicolor , 2008 .
[62] J. Verner,et al. Nest-site habitat of cavity-nesting birds at the San Joaquin Experimental Range , 2008 .
[63] D. Whisson,et al. Home Range and Movements of Roof Rats (Rattus rattus) in an Old-growth Riparian Forest, California , 2007 .
[64] Bruce A. Robertson,et al. Is Selectively Harvested Forest an Ecological Trap for Olive-Sided Flycatchers?¿Es el Aprovechamiento Selectivo de los Bosques una Trampa Ecológica para Contopus cooperi?Harvested Forest as an Ecological Trap , 2007 .
[65] D. Ardia. GEOGRAPHIC VARIATION IN THE TRADE-OFF BETWEEN NESTLING GROWTH RATE AND BODY CONDITION IN THE TREE SWALLOW , 2006 .
[66] J. Pérez,et al. Nest box orientation affects internal temperature and nest site selection by Tree Swallows , 2006 .
[67] M. Patten,et al. Ecological traps in isodars: effects of tallgrass prairie management on bird nest success , 2005 .
[68] L. Tomiałojć,et al. Nest sites, nest depredation, and productivity of avian broods in a primeval temperate forest: do the generalisations hold? , 2005 .
[69] R. Dawson,et al. The importance of microclimate variation in determining size, growth and survival of avian offspring: experimental evidence from a cavity nesting passerine , 2005, Oecologia.
[70] Michael J. Stauss,et al. Foraging flight distances as a measure of parental effort in blue tits Parus caeruleus differ with environmental conditions , 2005 .
[71] N. N.,et al. EFFECTS OF WEATHER AND POPULATION DENSITY ON REPRODUCTIVE SUCCESS AND POPULATION DYNAMICS IN A SONG SPARROW ( MELOSPIZA MELODIA ) POPULATION : A LONG-TERM STUDY , 2005 .
[72] J. Battin. When Good Animals Love Bad Habitats: Ecological Traps and the Conservation of Animal Populations , 2004 .
[73] L. Johnson,et al. The Process and Causes of Fledging in a Cavity‐Nesting Passerine Bird, the House Wren (Troglodytes aedon) , 2004 .
[74] Kevin P. Price,et al. Relations between NDVI and tree productivity in the central Great Plains , 2004 .
[75] Henrik G. Smith,et al. Landscape composition affects habitat use and foraging flight distances in breeding European starlings , 2003 .
[76] A. Radford,et al. The importance of rainfall to a cavity-nesting species , 2003 .
[77] S. A. Morrison,et al. Variation in a sparrow's reproductive success with rainfall: food and predator-mediated processes , 2002, Oecologia.
[78] A. Radford,et al. Activity patterns of parent Great Tits Parus major feeding their young during rainfall , 2001 .
[79] R. Rosenfield,et al. SPECIES-SPECIFIC EDGE EFFECTS ON NEST SUCCESS AND BREEDING BIRD DENSITY IN A FORESTED LANDSCAPE , 2001 .
[80] G. Bortolotti,et al. REPRODUCTIVE SUCCESS OF AMERICAN KESTRELS: THE ROLE OF PREY ABUNDANCE AND WEATHER , 2000 .
[81] C. F. Thompson,et al. Food-supplementation does not override the effect of egg mass on fitness-related traits of nestling house wrens , 2000 .
[82] C. F. Thompson,et al. Fitness–related consequences of egg mass in nestling house wrens , 1999, Proceedings of the Royal Society of London. Series B: Biological Sciences.
[83] Jörg Kaduk,et al. Comparing global models of terrestrial net primary productivity (NPP): comparison of NPP to climate and the Normalized Difference Vegetation Index (NDVI) , 1999 .
[84] J. Verner,et al. A COMPARISON OF THE BREEDING ECOLOGY OF BIRDS NESTING IN BOXES AND TREE CAVITIES , 1997 .
[85] C. Tucker,et al. Increased plant growth in the northern high latitudes from 1981 to 1991 , 1997, Nature.
[86] B. Young. GEOGRAPHIC AND SEASONAL PATTERNS OF CLUTCH-SIZE VARIATION IN HOUSE WRENS , 1994 .
[87] T. E. Martin. Nest Predation and Nest SitesNew perspectives on old patterns , 1993 .
[88] J. Wiens,et al. WEATHER AND REPRODUCTIVE VARIATION IN SHRUBSTEPPE SPARROWS: A HIERARCHICAL ANALYSIS' , 1991 .
[89] Pingjun Li,et al. Nest-Site Selection and Nesting Success of Cavity-Nesting Birds in High Elevation Forest Drainages , 1991 .
[90] C. F. Thompson,et al. Mate switching in multibrooded House Wrens , 1991 .
[91] C. F. Thompson,et al. Evolution of clutch size: an experimental test in the house wren (Troglodytes aedon) , 1987 .
[92] C. D. Ankney,et al. Sources of Variation in Growth of Tree Swallows , 1986 .
[93] S. Moore,et al. Weather related mortality in swallows in the Sacramento Valley of California , 1985 .
[94] M. T. Murphy. Nestling Eastern Kingbird Growth: Effects of Initial Size and Ambient Temperature , 1985 .
[95] S. Nilsson. The evolution of nest-site selection among hole-nesting birds: the importance of nest predation and competition , 1984 .
[96] N. Nur. The Consequences of Brood Size for Breeding Blue Tits II. Nestling Weight, Offspring Survival and Optimal Brood Size , 1984 .
[97] L. W. Gysel,et al. Avian Nest Dispersion and Fledging Success in Field‐Forest Ecotones , 1978 .