Date:
September 10, 2014
Source: DOE/Princeton
Plasma Physics Laboratory
Summary:
Magnetic reconnection can trigger
geomagnetic storms that disrupt cell phone service, damage satellites and black
out power grids. But how reconnection, in which the magnetic field lines in
plasma snap apart and violently reconnect, transforms magnetic energy into
explosive particle energy remains a major unsolved problem in plasma
astrophysics.
Magnetic reconnection can trigger
geomagnetic storms that disrupt cell phone service, damage satellites and black
out power grids. But how reconnection, in which the magnetic field lines in
plasma snap apart and violently reconnect, transforms magnetic energy into
explosive particle energy remains a major unsolved problem in plasma
astrophysics. Magnetic field lines represent the direction, and indicate the
shape, of magnetic fields.
Now
scientists at the U.S. Department of Energy's (DOE) Princeton Plasma Physics
Laboratory (PPPL) have taken a key step toward a solution, as described in a
paper published this week in the journal Nature Communications. In
research conducted on the Magnetic Reconnection Experiment (MRX) at PPPL, the
scientists not only identified how the mysterious transformation takes place,
but measured experimentally the amount of magnetic energy that turns into
particle energy.
The
investigation showed that reconnection converts about 50 percent of the
magnetic energy, with one-third of the conversion heating the electrons and
two-thirds accelerating the ions -- or atomic nuclei -- in the plasma. In large
bodies like the sun, such converted energy can equal the power of millions of
tons of TNT.
"This
is a major milestone for our research," said Masaaki Yamada, the principal
investigator for the MRX and first author of the Nature Communications paper.
"We can now see the entire picture of how much of the energy goes to the
electrons and how much to the ions in a prototypical reconnection layer."
The
findings also suggested the process by which the energy conversion occurs.
Reconnection first propels and energizes the electrons, according to the
researchers, and this creates an electrically charged field that "becomes
the primary energy source for the ions," said Jongsoo Yoo, a postdoctoral
fellow at PPPL and coauthor of the paper. Also contributing to the paper were
physicists Hantao Ji and Russell Kulsrud, and doctoral candidates Jonathan
Jara-Almonte and Clayton Myers.
If
confirmed by data from space explorations, the PPPL results could help resolve
decades-long questions and create practical benefits. These could include a
better understanding of geomagnetic storms that could lead to advanced warning
of the disturbances and an improved ability to cope with them. Researchers
could shut down sensitive instruments on communications satellites, for
example, to protect the instruments from harm.
The
PPPL team will eagerly watch a four-satellite mission that NASA plans to launch
next year to study reconnection in the magnetosphere -- the magnetic field that
surrounds Earth. The team plans to collaborate with the venture, called the
Magnetospheric Multiscale (MMS) Mission, by providing MRX data to it. The MMS
probes could help to confirm the Laboratory's findings.
This
work was supported by the DOE Office of Science.
Story
Source:
The
above story is based on materials provided by DOE/Princeton
Plasma Physics Laboratory. Note: Materials may be edited for
content and length.
Journal
Reference:
1.
Masaaki Yamada, Jongsoo Yoo,
Jonathan Jara-Almonte, Hantao Ji, Russell M. Kulsrud, Clayton E. Myers. Conversion
of magnetic energy in the magnetic reconnection layer of a laboratory plasma.
Nature Communications, 2014; 5: 4774 DOI: 10.1038/ncomms5774
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