A sophisticated molecule may be what drives a bird's internal global positioning system (GPS).

Under illumination, the molecule is sensitive to both the magnitude and the direction of magnetic fields as tiny as the Earth’s -- which is about one-twenty thousandth stronger than a refrigerator magnet.

Scientists from Arizona State University (ASU) and the University of Oxford who have synthesized and studied the molecule said their results "provide clear proof of principle that the magnetic compass sense of migratory birds is based on a magnetically sensitive chemical reaction whose product yields or rate depend on the orientations of the molecules involved with respect to the geomagnetic field," ASU said in a statement.

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An international team of researchers are the first to demonstrate that a synthesized photochemical molecule composed of linked carotenoid (C), porphyrin (P) and fullerene (F) units can act as a magnetic compass. When excited with light, CPF forms a short-lived charge-separated state with a negative charge on the ball-like fullerene unit and a positive charge on the rod-like carotenoid unit. The lifetime of the charge-separated state before it returns to its lowest energy or ground state is sensitive to the magnitude and direction of a weak magnetic field similar to Earth's. (Image: Zina Deretsky, National Science Foundation)

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ASU’s Devens Gust, a professor of chemistry and biochemistry at ASU, said, “Although the chemical magnetoreception mechanism for avian magnetic navigation has been discussed by many investigators, our research provides the first proof that this mechanism can actually function with magnetic fields as small as those of the Earth.

"This work has demonstrated that the ingenious chemical magnetoreception concept is indeed feasible," he said. "It certainly provides some insight into the structure and dynamic design features needed for a molecular interpretation of how the birds go about keeping their appointments in strange places across the world."

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Devens Gust (photo courtesy Arizona State University)

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Gust -- who is also a faculty researcher at ASU's Center for Bioenergy and Photosynthesis -- said the design, synthesis and a few initial magnetic field effect studies were done at ASU in the context of artificial photosynthetic solar energy conversion. The Oxford group, led by chemistry professor Peter Hore, realized these effects might be relevant to chemical magnetoreception, constructed the extremely sensitive apparatus needed to observe the phenomena and carried out the appropriate experiments.

It has long been known that birds and many other animals including turtles, salamanders and lobsters, use the Earth’s magnetic field to navigate, but the nature of their global positioning systems has not been completely understood, ASU said in a statement. "One school of thought hypothesizes that birds use magnetically sensitive chemical reactions initiated by light (called chemical magnetoreception) to orient themselves, but no chemical reaction in the laboratory, until now, has been shown to respond to magnetic fields as weak as the Earth’s."

Ten years ago, a National Science Foundation-sponsored research team at ASU led by Gust, Thomas Moore and Ana Moore, synthesized a molecular "triad" and demonstrated that when the triad was exposed to light, it formed a short-lived, high-energy charge-separated species whose lifetime was influenced by magnetic fields. "The special molecules were originally synthesized as artificial photosynthetic reaction centers, being developed as chemical solar energy conversion systems. They were inspired by the way plants harvest sunlight, and had nothing whatsoever to do with bird navigation," ASU said.

A related triad molecule was recently synthesized by Paul Liddell, assistant research professional working with Gust and the Moores, and studied by Hore and coworkers at the University of Oxford. The British researchers used lasers that sent out pulses of light lasting only one-thousand-millionths of a second to investigate the molecular properties. A major problem was to completely shield their experiments from the Earth’s magnetic field, ASU said.

The "wonder molecule" comprises three units, a carotene-porphyrin-fullerene triad. When excited by light, the triad molecule forms a charge-separated state with the negative charge on the soccer-ball-like fullerene (or buckyball) portion and the positive charge on the rod-like carotene portion. The lifetime of the charge-separated species before it returns to the normal state is sensitive to the magnitude and direction of a weak magnetic field, similar to that of the Earth. The triad molecule, in its charge-separated state, could be thought of as having little bar magnets at either end so far apart that they interact with each other only weakly.

Gust said understanding animal navigation systems is of great ecological importance because weak, manmade magnetic fields are produced by many widely used technologies, such as power lines and communications equipment. In fact, this also allows for a diagnostic test of the magnetoreceptor mechanism, he said. Research has shown that both broadband radio noise (0.1-10.0 MHz) and constant frequency (7MHz) signals disrupted magnetic orientation in European robins.

"Of course," Gust said, "this research does not prove that birds actually use this mechanism, only that they could. But there is a large body of research on birds that is consistent with the magnetoreception idea."

Gust and Liddell were joined in the research by Kiminori Maeda, Kevin Henbest and Christiane Timmel of the University of Oxford’s inorganic chemistry laboratory and Filippo Cintolesi, Ilya Kuprov, Christopher Rodgers and Hore of Oxford’s physical chemistry laboratory.

ASU said the international research team is designing new molecules and experiments to further their case. Their work, supported by the National Science Foundation (Division of Chemistry award number 0352599), appears in the April 30 online publication of the journal Nature.

For more information, visit: www.asu.edu