Abstract
Temperature is one of the best investigated environmental factors in ecological life-history studies and is increasingly considered in the contexts of climate change and urbanization. In avian ecology, few studies have examined the associations between thermal dynamics in the nest environment and its neighbouring air. Here, we placed avian nests and non-incubated eggs inside nest boxes at various air temperatures that ranged from 0.3 to 33.1 °C, both in the field and in laboratory conditions. We measured how the design of the boxes, their compass orientation and their location in more or less urbanized environments affected the surface temperature of nests and eggs. We also assessed whether covering the eggs with lining material influenced their surface temperature. Overall, across all performed tests, we found that the surface temperature of nests and eggs strongly reflected the air temperature measured outside of the nest boxes. While the design of the nest boxes had little influence on the temperature of nests and eggs, orienting the nest boxes to the north or to the west significantly decreased their surface temperature. The presence of lining material also kept eggs slightly warmer when air temperatures were low. Altogether these results suggest that non-incubated eggs are not well protected against extreme air temperatures prior to the onset of incubation. From an evolutionary point of view, producers of ectotherm eggs need therefore to time egg-laying appropriately in order to avoid unfavourable thermal nest environments.
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Acknowledgements
This work was supported by the city of Montpellier, the University of Montpellier, OSU-OREME, and the Mediterranean Centre for Environment and Biodiversity (LabEx CeMEB). Nicolas Lambrechts helped with monitoring. We thank Arnaud Grégoire, Stéphanie Grosset, Thierry Noell, Pascal Pagano, Vincent Perret and Gilles Tessier for their logistic support. We thank three anonymous reviewers for their very constructive comments on earlier versions of this manuscript.
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Lambrechts, M.M., Caizergues, A.E., Perrier, C. et al. Surface temperatures of non-incubated eggs in great tits (Parus major) are strongly associated with ambient temperature. Int J Biometeorol 64, 1767–1775 (2020). https://doi.org/10.1007/s00484-020-01958-1
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DOI: https://doi.org/10.1007/s00484-020-01958-1