The quantum needle of the avian magnetic compass
Abstract
Billions of birds fly thousands of kilometers every year between their breeding and wintering grounds, helped by an extraordinary ability to detect the direction of the Earth’s magnetic field. The biophysical sensory mechanism at the heart of this compass is thought to rely on magnetically sensitive, light-dependent chemical reactions in cryptochrome proteins in the eye. Thus far, no theoretical model has been able to account for the <5° precision with which migratory birds are able to detect the geomagnetic field vector. Here, using computer simulations, we show that genuinely quantum mechanical, long-lived spin coherences in realistic models of cryptochrome can provide the necessary precision. The crucial structural and dynamical molecular properties are identified.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Apr 04, 2016
- Source ID
- 10.1073/pnas.1600341113
Entities
People
- Charlotte Steers
- Daniel R. Kattnig
- David Manolopoulos
- Hamish G. Hiscock
- Henrik Mouritsen
- Jin Ye
- P. J. Hore
- Susannah Worster
Organizations
- Air Force Office of Scientific Research
- EMF Biological Research Trust
- European Research Council
- German Research Foundation
- University of Oldenburg
- University of Oxford
- Volkswagen Foundation