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August
31, 2009: Magnetic reconnection could be the Universe's
favorite way to make things explode. It operates anywhere
magnetic fields pervade space--which is to say almost everywhere.
On the sun magnetic reconnection causes solar flares as powerful
as a billion atomic bombs. In Earth's atmosphere, it fuels
magnetic storms and auroras. In laboratories, it can cause
big problems in fusion reactors. It's ubiquitous.
 The
problem is, researchers can't explain it.
The
basics are clear enough. Magnetic lines of force cross, cancel,
reconnect and—Bang! Magnetic energy is unleashed in the form
of heat and charged-particle kinetic energy.
Right:
A cartoon model of magnetic reconnection on the sun. [more]
But
how? How does the simple act of crisscrossing magnetic field
lines trigger such a ferocious explosion?
"Something
very interesting and fundamental is going on that we don't
really understand -- not from laboratory experiments or from
simulations," says Melvyn Goldstein, chief of the Geospace
Physics Laboratory at NASA's Goddard Space Flight Center.
NASA
is going to launch a mission to get to the bottom of the mystery.
It's called MMS, short for Magnetospheric Multiscale Mission,
and it consists of four spacecraft which will fly through
Earth's magnetosphere to study reconnection in action. The
mission passed its preliminary design review in May 2009 and
was approved for implementation in June 2009. Engineers can
now start building the spacecraft.
"Earth's
magnetosphere is a wonderful natural laboratory for studying
reconnection," says mission scientist Jim Burch of the
Southwest Research Institute. "It is big, roomy, and reconnection
is taking place there almost non-stop."
In
the outer layers of the magnetosphere, where Earth's magnetic
field meets the solar wind, reconnection events create temporary
magnetic "portals" connecting Earth to the sun.
Inside the magnetosphere, in a long drawn-out structure called
"the magnetotail," reconnection propels high-energy
plasma clouds toward Earth, triggering Northern Lights when
they hit. There are many other examples, and MMS will explore
them all.
The
four spacecraft will be built at the Goddard Space Flight
Center. "Each observatory is shaped like a giant hockey
puck, about 12 feet in diameter and 4 feet in height,"
says Karen Halterman, MMS Project Manager at Goddard.
Above:
An artist's concept of the four MMS spacecraft flying in formation
through the space around Earth. [more]
The
mission's sensors for monitoring electromagnetic fields and
charged particles are being built at a number of universities
and laboratories around the country, led by the Southwest
Research Institute. When the instruments are done, they will
be integrated into the spacecraft frames at Goddard. Launch
is scheduled for 2014 onboard an Atlas V rocket.
Any
new physics MMS learns could ultimately help alleviate the
energy crisis on Earth.
"For
many years, researchers have looked to fusion as a clean and
abundant source of energy for our planet," says Burch.
"One approach, magnetic confinement fusion, has yielded
very promising results with devices such as tokamaks. But
there have been problems keeping the plasma (hot ionized gas)
contained in the chamber."
 "One
of the main problems is magnetic reconnection," he continues.
"A spectacular and even dangerous result of reconnection
is known as the sawtooth crash. As the heat in the tokamak
builds up, the electron temperature reaches a peak and then
'crashes' to a lower value, and some of the hot plasma escapes.
This is caused by reconnection of the containment field."
Right:
Inside a tokamak. Image credit: Lawrence Berkeley Labs [more]
In
light of this, you might suppose that tokamaks would be a
good place to study reconnection. But no, says Burch. Reconnection
in a tokamak happens in such a tiny volume, only a few millimeters
wide, that it is very difficult to study. It is practically
impossible to build sensors small enough to probe the reconnection
zone.
Earth's
magnetosphere is much better. In the expansive magnetic bubble
that surrounds our planet, the process plays out over volumes
as large as tens of kilometers across. "We can fly spacecraft
in and around it and get a good look at what's going on,"
he says.
That
is what MMS will do: fly directly into the reconnection zone.
The spacecraft are sturdy enough to withstand the energetics
of reconnection events known to occur in Earth's magnetosphere,
so there is nothing standing in the way of a full two year
mission of discovery.
Learn
more about the mission at the MMS
Home Page.
Author: Dr.
Tony Phillips | Credit: Science@NASA
| more
information |
| MMS
Brochure
MMS
home pages: SWRI,
NASA,
Rice University
MMS
Credits: Science team members and instrument
development are provided by the University of New Hampshire;
Johns Hopkins University Applied Physics Laboratory;
NASA Goddard; University of Colorado; Lockheed Martin
Advanced Technology Center; Rice University; the University
of Iowa; Aerospace Corporation; and the University of
California-Los Angeles. International contributions
to the MMS instrument suite are provided by the Austrian
Academy of Sciences; Sweden's Royal Institute of Technology
and Institute of Space Physics; France's Plasma Physics
Laboratory and Toulouse Space Center; and Japan's Institute
of Space and Astronautical Science.
MMS
is a NASA Science Mission Directorate Heliophysics mission
in the Solar Terrestrial Probes Program. MMS is managed
by NASA Goddard. Kennedy Space Center is providing launch
services.
NASA's
Magnetospheric MultiScale Mission Takes a Step Closer
to Solving the Mystery Behind Magnetic Reconnection
-- NASA
Magnetospheric
Multiscale Mission Orbit Animation
--from Goddard's Scientific Visualization Studio
NASA's
Future: US
Space Exploration Policy |
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