Shifting latitudinal clines in avian body size correlate with global warming in Australian passerines
about
Novel communities from climate changeNon-repeatable science: assessing the frequency of voucher specimen deposition reveals that most arthropod research cannot be verifiedGenetic population structure accounts for contemporary ecogeographic patterns in tropic and subtropic-dwelling humansClimate warming and Bergmann's rule through time: is there any evidence?Leaf morphology shift linked to climate changeClimate change impacts on body size and food web structure on mountain ecosystems.Annual plants change in size over a century of observations.Mechanistic models for the spatial spread of species under climate change.Temperatures in excess of critical thresholds threaten nestling growth and survival in a rapidly-warming arid savanna: a study of common fiscals.Increases in disturbance and reductions in habitat size interact to suppress predator body size.Morphological change to birds over 120 years is not explained by thermal adaptation to climate changeContrasting effects of climate on juvenile body size in a Southern Hemisphere passerine bird.Unpacking the mechanisms captured by a correlative species distribution model to improve predictions of climate refugia.Are long-term widespread avian body size changes related to food availability? A test using contemporaneous changes in carotenoid-based color.Long-term continental changes in wing length, but not bill length, of a long-distance migratory shorebird.Counter-gradient variation in respiratory performance of coral reef fishes at elevated temperatures.Allen's rule revisited: quantitative genetics of extremity length in the common frog along a latitudinal gradient.Recent spatial and temporal changes in body size of terrestrial vertebrates: probable causes and pitfalls.Do species' traits predict recent shifts at expanding range edges?Diatoms can be an important exception to temperature-size rules at species and community levels of organization.Natural history collections as windows on evolutionary processes.Are latitudinal clines in body size adaptive?Climate change and body size trends in aquatic and terrestrial endotherms: Does habitat matter?Incorporating population-level variation in thermal performance into predictions of geographic range shifts.Higher temperatures during development reduce body size in the zebra finch in the laboratory and in the wild.Tests of ecogeographical relationships in a non-native species: what rules avian morphology?No general relationship between mass and temperature in endothermic species.Genetic correlations and sex-specific adaptation in changing environments.Evolution, climate change, and extreme events.Adaptation to climate change: contrasting patterns of thermal-reaction-norm evolution in Pacific versus Atlantic silversides.Meta-analysis at the intersection of evolutionary ecology and conservationPatterns in body size and melanism along a latitudinal cline in the wingless grasshopper, Phaulacridium vittatum
P2860
Q27026921-401B2430-B010-468F-9328-8C1B0CB65227Q28608121-77887582-578B-4BA3-9751-3743EF72F52AQ28651181-4F3C08A4-2F5C-4847-AAD9-B805E57F72C1Q28660548-AC0B383F-CA91-4802-A525-C1F66BD4B9D5Q28727843-9EE554C7-1224-474C-AC83-69E499B2B88EQ30570477-3822D7B5-21E3-4BC4-A2D8-B0905548B4FBQ30607246-121B08D3-4111-4293-BCAA-B6B9200E15DEQ30655864-351C31DF-5D31-49BB-B78B-CB464DA5B6ACQ30667220-2498C2DD-4FAE-4736-BA8F-8C987461631FQ30679162-35A62F9C-81FC-4031-B780-2F61EBAEBBE8Q30836334-57ECEEDF-A36B-412B-BECB-0C790A1BAD8AQ30968568-4047B536-E093-4CB1-B3E2-DCF7AF6B997EQ31056083-6CEBE1DE-F57C-4E1C-9BFE-CF66C34D04C9Q33633781-72D5778F-53B0-4D7A-9107-CE299819CCC5Q33633916-A69537E3-21B9-4BB8-B670-C00F42C08B25Q33719270-7DD1966E-D11C-4E2C-970F-907F60DF293EQ33724656-CD1FE4B2-29C6-4171-8CA7-4F426715A215Q33744376-D1CF8B8B-CF09-4149-BDCA-3C03FC9DD09EQ33887430-A4D66E89-B6B3-49F7-B6C6-810AEACBDEAAQ34746857-AC26BD63-435F-47B6-BE8F-A576606A33E8Q35891673-62CA38B9-B21D-4FBE-8A5E-D16DF1756C53Q36353743-F4873DBA-0260-4CB4-B39D-E8DEC92AF820Q38368166-59021BBA-9445-47BF-992F-3B1D8A6FDC1AQ43710259-DB7A32E9-EB36-4BF7-8B1C-E6C67CA39802Q46295177-D7A8EAEA-3CD8-4A94-A088-E7C82FE7CD7AQ46586319-1460A675-0BB0-4576-BB78-3412474D3465Q47192376-34C5A24B-A66E-481E-989E-24A6068C1A69Q48032979-C9DD5C12-84E5-4045-9829-2CA9C2939ECDQ50246333-18EEABF3-C437-4CC4-A4D8-BF2DD490EBFFQ55332357-FC2A103C-5FF1-4041-9749-E916C9D266FDQ56548507-8D78B846-3ADD-4759-B3E7-E0A605AB35EEQ57032325-5F2F6CA8-6DC4-4D1B-BEBD-9B3441FFB3B7
P2860
Shifting latitudinal clines in avian body size correlate with global warming in Australian passerines
description
article
@en
im November 2009 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в листопаді 2009
@uk
name
Shifting latitudinal clines in ...... rming in Australian passerines
@en
Shifting latitudinal clines in ...... rming in Australian passerines
@nl
type
label
Shifting latitudinal clines in ...... rming in Australian passerines
@en
Shifting latitudinal clines in ...... rming in Australian passerines
@nl
prefLabel
Shifting latitudinal clines in ...... rming in Australian passerines
@en
Shifting latitudinal clines in ...... rming in Australian passerines
@nl
P2093
P2860
P356
P1476
Shifting latitudinal clines in ...... rming in Australian passerines
@en
P2093
Janet L Gardner
Leo Joseph
Robert Heinsohn
P2860
P304
P356
10.1098/RSPB.2009.1011
P407
P577
2009-11-07T00:00:00Z