TY - JOUR
T1 - Global population dynamics and hot spots of response to climate change
AU - Post, Eric
AU - Brodie, Jedediah
AU - Hebblewhite, Mark
AU - Anders, Angela D.
AU - Maier, Julie A.K.
AU - Wilmers, Christopher C.
N1 - Funding Information:
This article resulted from a workshop organized by E. P. at the Aarhus University, Denmark, supported by a grant to E. P. from the National Science Foundation (NSF). We thank the participants of that workshop for stimulating and inspiring discussions: Peter Aastrup, Mads C. Forchhammer, Ditte Hendrichsen, Toke T. Høye, Jacob Nabe-Nielsen, Niels Martin Schmidt, Chris Topping, and Mary Wisz. Comments by three anonymous referees are gratefully acknowledged. A. D. A. was supported by a graduate fellowship from Pennsylvania State University, and J. B. by the David H. Smith Conservation Research Fellowship. C. C. W. was supported by the NSF, and M. H. was supported by the University of Montana and the Canadian Association of Petroleum Producers.
PY - 2009/6
Y1 - 2009/6
N2 - Understanding how biotic and abiotic factors influence the abundance and distribution of organisms has become more important with the growing awareness of the ecological consequences of climate change. In this article, we outline an approach that complements bioclimatic envelope modeling in quantifying the effects of climate change at the species level. The global population dynamics approach, which relies on distribution-wide, datadriven analyses of dynamics, goes beyond quantifying biotic interactions in population dynamics to identify hot spots of response to climate change. Such hot spots highlight populations or locations within species' distributions that are particularly sensitive to climate change, and identification of them should focus conservation and management efforts. An important result of the analyses highlighted here is pronounced variation at the species level in the strength and direction of population responses to warming. Although this variation complicates species-level predictions of responses to climate change, the global population dynamics approach may improve our understanding of the complex implications of climate change for species persistence or extinction.
AB - Understanding how biotic and abiotic factors influence the abundance and distribution of organisms has become more important with the growing awareness of the ecological consequences of climate change. In this article, we outline an approach that complements bioclimatic envelope modeling in quantifying the effects of climate change at the species level. The global population dynamics approach, which relies on distribution-wide, datadriven analyses of dynamics, goes beyond quantifying biotic interactions in population dynamics to identify hot spots of response to climate change. Such hot spots highlight populations or locations within species' distributions that are particularly sensitive to climate change, and identification of them should focus conservation and management efforts. An important result of the analyses highlighted here is pronounced variation at the species level in the strength and direction of population responses to warming. Although this variation complicates species-level predictions of responses to climate change, the global population dynamics approach may improve our understanding of the complex implications of climate change for species persistence or extinction.
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U2 - 10.1525/bio.2009.59.6.7
DO - 10.1525/bio.2009.59.6.7
M3 - Article
AN - SCOPUS:68349164279
SN - 0006-3568
VL - 59
SP - 489
EP - 497
JO - BioScience
JF - BioScience
IS - 6
ER -