Details

Autor(en) / Beteiligte

• Latimer, Christopher E.
• Zuckerberg, Benjamin
• White, Hannah

Titel

Habitat loss and thermal tolerances influence the sensitivity of resident bird populations to winter weather at regional scales

Ist Teil von

• The Journal of animal ecology, 2021-02, Vol.90 (2), p.317-329

Ort / Verlag

England: Blackwell Publishing Ltd

Erscheinungsjahr

2021

Link zum Volltext

Quelle

MEDLINE

Beschreibungen/Notizen

• Climate change and habitat loss pose the greatest contemporary threats to biodiversity, but their impacts on populations largely vary across species. These differential responses could be caused by complex interactions between landscape and climate change and species‐specific sensitivities. Understanding the factors that determine which species are most vulnerable to the synergistic effects of climate change and habitat loss is a high conservation priority. Here, we ask (a) whether and to what extent land cover moderates the impacts of winter weather on population dynamics of wintering birds, and (b) what role species’ physiology might play in modifying their responses to changing weather conditions. To address these questions, we used thousands of observations collected by citizen scientists participating in Project FeederWatch to build dynamic occupancy models for 14 species of wintering birds. Populations of wintering birds were more dynamic, having higher rates of local extinction and colonization, in more forested landscapes during extreme cold—presumably enabling them to better track resources. However, urban areas appeared to provide refuge for some species, as demonstrated by increased local colonization during the harshest winter weather. Lastly, we found that species‐specific differences in thermal tolerances strongly influenced occupancy dynamics such that species that are less cold‐tolerant were more likely to go locally extinct at colder sites and during colder periods throughout winter. Together, our results suggest that species that are less cold‐tolerant and populations occupying less forested landscapes are most vulnerable to extreme winter weather. Species‐specific thermal tolerances affect within‐winter regional occupancy dynamics, suggesting generalizable mechanistic links between community‐level responses and future climate changes. Photo credit: Jeremy Cohen