February 2012 | Home
After six years, editor John Lofy is leaving Michigan Today. His goodbye column includes a list of his favorite articles.
U-M's campus zoo delighted locals with bears, skunks, a fox, a host of turtles and one very angry wolverine.
Writer and law prof William Ian Miller's bleak and hilarious exploration of aging.
Rebuilding the men's and women's basketball programs has taken a few years, but both are now poised for long term success.
Second and third thoughts on a movie about the movies' early days.
A case where it might be fine to break the grammar rules.
An online magazine for alumni and friends of U-M.
Why is the universe magnetized?
February 15, 2012
Why is the universe magnetized? It's a question scientists have been asking for decades. Now, an international team of researchers including a University of Michigan professor have demonstrated that it could have happened spontaneously, as the prevailing theory suggests.
The findings are published in the Jan. 26 edition of Nature. Oxford University scientists led the research.
"According to our previous understanding, any magnetic field that had been made ought to have gone away by now," said Paul Drake, the Henry S. Carhart Collegiate Professor of Atmospheric, Oceanic, and Space Sciences and a professor in physics at U-M. "We didn't understand what mechanism might create a magnetic field, and even if it happened, we didn't understand why the magnetic field is still there.
"It has been a very enduring mystery."
With high-energy pulsed lasers in a French laboratory, the researchers created certain conditions analogous to those in the early universe when galaxies were forming. Through their experiment, they demonstrated that the theory known as the Biermann battery process is likely correct.
Discovered by a German astronomer in 1950, the Biermann process predicts that a magnetic field can spring up spontaneously from nothing more than the motion of charged particles. Plasma, or charged particle gas, is abundant in space.
Scientists believe that large clouds of gas collapsing into galaxies sent elliptically shaped bubbles of shockwaves through the early universe, touching off flows of electric current in the plasma of the intergalactic medium.
Anyone who has built an electromagnet in middle school science class is familiar with this concept, Drake said.
"If you can make current flow, you make a magnetic field," Drake said.
The question in astrophysics was what could have generated the current. This experiment demonstrated that such asymmetrical shockwaves could do the job.
The results, Drake said, aren't particularly surprising. But it's important for scientists to test their theories with experiments.
"These results help strengthen the understanding that we've taken from our interpretation of astrophysical data," Drake said. "And understanding the universe and most definitely the origin of life is one of the great human intellectual quests."
The paper is titled "Generation of scaled protogalactic seed magnetic fields in laser produced shock waves." Other co-authors are from the University of Oxford, Rutherford Appleton Laboratory, Laboratoire pour l'Utilisation de Lasers Intenses, the University of Strathclyde, the University of California-Los Angeles, the University of York, the Institute of Laser Engineering at Osaka University, Lawrence Livermore National Laboratory and Wolfgang-Pauli-Strasse. The work is funded by the European Research Council, Laserlab-Europe, the Science and Technology Facilities Council, and the Engineering and Physical Sciences Research Council of the United Kingdom.