Animal-Environment Interactions

We strive to unveil the inner workings of ecological and evolutionary processes in the natural world  through a quantitative and predictive understanding of how the ever-changing environmental conditions impact on animals in the wild, the decisions they evolved to take, and the choices they have learned to make. Our vision is thus a quantitative understanding of how animals depend on, react to, and change their environment by studying their occurrence, distribution and foremost their movements in acknowledgment of the complexity of the evolutionary as well as ecological causes and consequences of these animal-environment interactions.

Ongoing projects

Drylands Project and Vulture Research Consortium
This initiative aims at bringing together a consortium of data owners to study vultures as indicator species of drylands globally, investigating how their movement interacts with water availability and thus can be indicative of desertification processes. more
MoveApps and move R-library
In the MoveApps project we are creating a platform to make sophisticated analytical tools accessible to a larger audience. Users are invited to combine multiple analysis Apps to create a Workflow that analyses data from the Movebank database. The Apps are created by the MoveApps team or the broader coding community in R, R-shiny or other languages. Our goal is to bring together movement ecologists and wildlife managers looking for flexible analysis tools with those who are developing tools and want to share them with others.
Energy sea-scapes for terrestrial bird migration

Energy sea-scapes for terrestrial bird migration

Our expectation of where animals should and should not be is based on where we, and generations before us, have observed them. We have not always looked for animals in places inconvenient for us to get to, but that does not mean that these places are inconvenient for the animals as well. With bio-logging technology, we are finding that animals regularly move through regions that we thought were “inhospitable”. In this project, we investigate how the atmospheric environment can facilitate terrestrial birds’ flight over the open sea.
Ontogeny of soaring flight

Ontogeny of soaring flight

Flight behavior is, at least partially, progressively acquired during a bird's early life stages. In soaring birds, this process involves learning to interact with the physical environment to effectively extract energy from it. How well and how fast an individual learns to soar can depend on morphological and cognitive traits, and its physical and social environment. The resulting individual variation can influence success later on in life, in foraging, migration, or survival. We explore this topic in various scales, from post-fledging flights of golden eagles to migratory route selection in European honey buzzards.
Seabirds and storms

Seabirds and storms

Seabirds have evolved to utilize the windscape to fuel their flight. Despite this, they can be impacted negatively by anomalies in wind conditions. How susceptible different species are to storms depends, at least partially, on their flight style. This is reflected in the reports of seabird wrecks, with flap gliders such as auks wrecked more often than dynamic soaring birds such as albatrosses. We investigate the use of the windscape by multiple seabird species to estimate the threshold of wind conditions tolerated by birds with different flight strategies. This project is led by Prof. Emily Shepard (Swansea University, UK).

In the Media

boar

Wearables for Wild Boar Prove That Accelerometer Readings Can Track African Swine Fever more

wild boar

Schweinepest: Sensoren erkennen kranke Wildschweine more

National Geographic

National Geographic

May 12, 2023

Fliegen mit dem Klimawandel more

ARTE

ARTE

May 11, 2023

Durch das bayerische Alpenland more

storm over ocean with eye of storm visible

Dunia Hewan more

Show more
Go to Editor View