Vision-based animal magnetoreception

Imagine if you had a superpower like sensing Earth's magnetic field! Many creatures, like salmon, sea turtles, lobsters, honeybees, and even fruitflies, actually have this ability. They use it to navigate and find their way around. One fascinating example is migratory birds, such as European robins and silvereyes, who rely on Earth's magnetic field to guide them during their long journeys.

Panoramic view at Frankfurt am Main, Germany

The bird's magnetic compass is like a secret superpower hidden in their eyes. It's not just any light that activates it; they need blue light to sense the magnetic field. This compass can detect changes in the inclination of magnetic field lines. Still, it's not bothered by the polarity of the field lines. Birds are also picky about the strength of the magnetic field, but they can adapt to higher or lower strengths over time.

On the technical side, our team has delved into the mathematical intricacies of understanding the bird's remarkable magnetic sense. We aim to decipher the impact of the magnetic field on what birds perceive through their retinas. Our studies have investigated various factors influencing the efficacy of the "bird compass." We've specifically studied the role of cryptochrome, which could impact the clarity of a bird's magnetic vision. Additionally, we've explored how the patterns seen by birds during day and night flights might affect the utilization of their magnetic compass. Our research has allowed us to step into the captivating realm of a bird's advanced navigation system, unraveling the secrets behind its high-tech capabilities!

Recent Publications

Solvent driving force ensures fast formation of a persistent and well-separated radical pair in plant cryptochrome, Gesa Lüdemann, Ilia A. Solov'yov, Tomáš Kubař, Marcus Elstner, Journal of the American Chemical Society, 137, 1147-1156, (2015)
Separation of photo-induced radical pair in cryptochrome to a functionally critical distance, Ilia A. Solov'yov, Tatiana Domratcheva, Klaus Schulten, Scientific Reports, 4, 3845, (2014)
A chemical compass for bird navigation, Ilia A. Solov'yov, Thorsten Ritz, Klaus Schulten, Peter J. Hore, in: Quantum Effects in Biology, edited by: Masoud Mohseni and Yasser Omar and Greg Engel and Martin B. Plenio, 218-236, Cambridge University Press, (2014)
Light-Activated Magnetic Compass in Birds, Ilia A. Solov'yov, Walter Greiner, in: Exciting Interdisciplinary Physics: Quarks and Gluons / Atomic Nuclei / Relativity and Cosmology / Biological Systems, edited by: Walter Greiner, 481 — 492, Springer International Publishing Switzerland, (2013)
Decrypting Cryptochrome: Revealing the Molecular Identity of the Photoactivation Reaction, Ilia A. Solov'yov, Tatiana Domratcheva, Abdul Rehaman Moughal Shahi, Klaus Schulten, Journal of the American Chemical Society, 134, 18046-18052, (2012)