Chemical compass

The mechanism of a chemical compass

In the enchanting world of nature's mysteries, many migratory animals possess a remarkable compass-like sense known as "magnetoreception." This extraordinary ability enables them to embark on epic journeys guided by the Earth's magnetic field. Imagine songbirds taking to the skies, their internal compasses attuned to the subtle dance of our planet's geomagnetic forces. Recent behavioural experiments have unveiled a fascinating facet of this avian talent: some songbirds possess a light-activated magnetoreception. What makes this discovery even more captivating is that these birds rely on something other than traditional magnetic minerals for their celestial navigation. Instead, they seem to wield a chemical compass, a marvel rooted in quantum physics. At its core lies the enchanting concept of the "unstable radical-pair reaction," where two molecules come together to share a pair of electrons with correlated spin states. This reaction, like a finely tuned instrument, is exquisitely sensitive to the Earth's gentle magnetic whispers and can function as a celestial compass, allowing the birds to gauge their orientation with respect to the geomagnetic field.

With advanced computational techniques, we embark on a thrilling journey to explore the intricate dynamics of these chemical reactions. We study how they unfurl their secrets under ever-changing environmental conditions. At the heart of this research lies the promise of unlocking the hidden intricacies of our feathered friends' celestial navigation, bringing us one step closer to comprehending the mesmerizing mysteries of the animal kingdom.

Recent Publications

Computational reconstruction reveals a candidate magnetic biocompass to be likely irrelevant for magnetoreception, Ida Friis, Emil Sjulstok, Ilia A. Solov'yov, Scientific Reports, 7, 13908, (2017)
Multiscale description of avian migration: from chemical compass to behaviour modeling, J. Boiden Pedersen, Claus Nielsen, Ilia A. Solov'yov, Scientific Reports, 6, 36709, (2016)
Electron spin relaxation can enhance the performance of a cryptochrome-based magnetic compass sensor, Daniel R. Kattnig, Jakub K. Sowa, Ilia A. Solov'yov, P. J. Hore, New Journal of Physics, 18, 063007, (2016)
Electron spin relaxation in cryptochrome-based magnetoreception, Daniel R. Kattnig, Ilia A. Solov'yov, P. J. Hore, Physical Chemistry - Chemical Physics, 70, 12443-12456, (2016)
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)