Abstract
For procellariiform seabirds, wind and morphology are crucial determinants of flight costs and flight speeds. During chick‐rearing, parental seabirds commute frequently to provision their chicks, and their body mass typically changes between outbound and return legs. In Antarctica, the characteristic diurnal katabatic winds, which blow stronger in the mornings, form a natural experimental setup to investigate flight behaviors of commuting seabirds in response to wind conditions. We GPS‐tracked three closely related species of sympatrically breeding Antarctic fulmarine petrels, which differ in wing loading and aspect ratio, and investigated their flight behavior in response to wind and changes in body mass. Such information is critical for understanding how species may respond to climate change. All three species reached higher ground speeds (i.e., the speed over ground) under stronger tailwinds, especially on return legs from foraging. Ground speeds decreased under stronger headwinds. Antarctic petrels (Thalassoica antarctica; intermediate body mass, highest wing loading, and aspect ratio) responded stronger to changes in wind speed and direction than cape petrels (Daption capense; lowest body mass, wing loading, and aspect ratio) or southern fulmars (Fulmarus glacialoides; highest body mass, intermediate wing loading, and aspect ratio). Birds did not adjust their flight direction in relation to wind direction nor the maximum distance from their nests when encountering headwinds on outbound commutes. However, birds appeared to adjust the timing of commutes to benefit from strong katabatic winds as tailwinds on outbound legs and avoid strong katabatic winds as headwinds on return legs. Despite these adaptations to the predictable diurnal wind conditions, birds frequently encountered unfavorably strong headwinds, possibly as a result of weather systems disrupting the katabatics. How the predicted decrease in Antarctic near‐coastal wind speeds over the remainder of the century will affect flight costs and breeding success and ultimately population trajectories remains to be seen.
Highlights
Wind is a key feature of the environment that affects the flight costs of birds moving across their landscape to access their foraging grounds and breeding sites (e.g., Safi et al, 2013; Shepard et al, 2013)
We predicted that under tailwinds, birds would show a steeper increase in ground speed in response to wind speed on return legs compared with outbound legs, but to show an absence of this relationship or possibly the opposite pattern under cross-and headwinds based on previous observational studies (Spear & Ainley, 1997b)
Cape petrels and Antarctic petrels experienced on average smaller angles between flight direction and wind direction, and more headwinds, on their outbound compared with return legs (LSM; z > |5.60|, p < .001), while there was no significant difference between outbound and return legs for southern fulmars (LSM; z = 0.32, p = .999; Figure 7)
Summary
Wind is a key feature of the environment that affects the flight costs of birds moving across their landscape to access their foraging grounds and breeding sites (e.g., Safi et al, 2013; Shepard et al, 2013). Based on the differences in wing loading and aspect ratio, under tailwinds we expected Antarctic petrels to reach higher ground speeds under higher wind speeds, followed by southern fulmars and last cape petrels We expected this response to be reversed or possibly absent under headwinds and crosswinds based on previous observational studies (Spear & Ainley, 1997b). We predicted that under tailwinds, birds would show a steeper increase in ground speed in response to wind speed on return legs compared with outbound legs, but to show an absence of this relationship or possibly the opposite pattern under cross-and headwinds based on previous observational studies (Spear & Ainley, 1997b). We compared wind speed and wind direction data from our study period and the area utilized by the birds with historic data and simulated data from climate change scenarios for the future, to assess whether climate change may in the long term affect our study populations
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