The foraging behaviour of seabirds is dramatically affected by turbulence caused by natural coastal features and manmade ocean structures, new research has shown.
In a first-of-its-kind study, scientists from the UK and Germany used drones to provide a synchronised bird鈥檚 eye view of what seabirds see and how their behaviour changes depending on the movement of tidal flows beneath them.
The research focused on the wake of a tidal turbine structure set in a tidal channel 鈥� Strangford Lough in Northern Ireland 鈥� that has previously been identified as a foraging hotspot for terns.
, it showed that terns were more likely to actively forage over vortices (swirling patches of water).
However, eruptions of upwelling water (boils) ahead of the terns鈥� flight path prompted them to stay on course as they approached.
Writing in the Royal鈥檚 Society flagship biological research journal, , the researchers say their findings offer a never-before-seen insight into how tidal turbulence can impact foraging behaviours.
They also say it potentially gives them the ability to predict how species might respond to environmental changes such as the increased future development of ocean renewable energy sites and climate change.
The study was conducted by researchers from Queen鈥檚 University Belfast and the 麻豆传媒 (UK), and Bielefeld University (Germany).
Dr Lilian Lieber, Bryden Centre Research Fellow at Queen鈥檚 and the study鈥檚 lead investigator, said:
鈥淥ur research highlights the importance of identifying changes in local flow conditions due to ocean energy structures which can change the occurrence, scale and intensity of localised turbulence in the water. Through a fantastic interdisciplinary collaboration, we were able to track prevalent flow features and seabirds on thus far unobtainable scales, shedding new light on tern foraging associations with turbulence. We found that terns were more likely to actively forage over vortices, while conspicuous upwellings provided a strong physical cue even at some distance, leading them to investigate such features. This research can help us predict seabird responses to coastal change.鈥�
Co-investigator Professor Roland Langrock, Professor in Statistics and Data Analysis at Bielefeld, said:
鈥淚t is extremely exciting that we now have these incredibly detailed animal movement data, which allows us to investigate behavioural processes at effectively arbitrarily fine scales of animal decision-making. While it presented some new statistical challenges, the interdisciplinary nature of our project presents a valuable contribution to the emerging field of high-throughput movement ecology.鈥�
