Magnetic-Shield Cracks Found; Big Solar Storms Expected[via national geographic]
An unexpected, thick layer of solar particles inside Earth's magnetic field suggests there are huge breaches in our planet's solar defenses, scientists said.
These breaches indicate that during the next period of high solar activity, due to start in 2012, Earth will experience some of the worst solar storms seen in decades.
Solar winds—charged particles from the sun—help create auroras, the brightly colored lights that sometimes appear above the Earth's poles.
But the winds also trigger storms that can interfere with satellites' power sources, endanger spacewalkers, and even knock out power grids on Earth.
"The sequence we're expecting … is just right to put particles in and energize them to create the biggest geomagnetic storms, the brightest auroras, the biggest disturbances in Earth's radiation belts," said David Sibeck, a space-weather expert at NASA's Goddard Space Flight Center in Maryland.
"So if all of this is true, it should be that we're in for a tough time in the next 11 years."
Into the Breach
Data from NASA's THEMIS satellite showed that a 4,000-mile-thick (6,437-kilometer-thick) layer of solar particles has gathered and is rapidly growing within the outermost part of the magnetosphere, a protective bubble created by Earth's magnetic field.
Normally the magnetosphere blocks most of the solar wind, flowing outward from the sun at about a million miles (1.6 million kilometers) an hour.
"The solar wind is constantly changing, and the Earth's magnetic field is buffeted like a wind sock in gale-force winds, fluttering back and forth in response to the solar wind," Sibeck said this week during a meeting of the American Geophysical Union in San Francisco.
Earth's magnetic field lines align themselves in different directions over various regions of the planet.
Near Earth's Equator, where solar winds press against the magnetosphere, the field lines point north.
Solar winds also carry magnetic field lines toward Earth, and those solar field lines point in different directions during the sun's 11-year cycle of activity.
Conventional thinking had suggested that north-pointing field lines would act like reinforcements to Earth's northward field, causing the planet to "raise shields" against solar winds.
The idea is based, in part, on the fact that auroras are brighter and space-weather hazards increase when solar winds carry southward-pointing field lines, Sibeck said.
"So it's reasonable to think that during periods when the sun's magnetic field lines point south, that's when the most particles get into Earth's magnetosphere."
THEMIS, however, showed that the opposite is true.
The satellite system "found the solar particle layer is much thicker when the two fields are pointing in the same direction," said Marit Øieroset, a THEMIS scientist based at the University of California, Berkeley, who first saw the effect.
In fact, 20 times more particles get through Earth's magnetic shield when the field lines are aligned than when they are opposed, she said.
To find the mechanism behind this discovery, Oieroset and Sibeck turned to computer models that could simulate the conditions observed by THEMIS.
The models showed that the likely driver is north-facing field lines connecting with Earth's magnetosphere, said Jimmy Raeder, a physicist at the University of New Hampshire in Durham who helped build the simulations.
As a field line approaches, it latches onto the poles and wraps around the planet like an octopus using a tentacle to snare its prey, he said.
The latching, known as magnetic reconnection, tears huge cracks in the magnetosphere and allows solar plasma to leak in.
"We have other observations from other satellites that this reconnection process happens over the poles at times, but we had never appreciated what it actually does," Raeder said.
A thicker layer of solar particles, however, isn't enough by itself to create geomagnetic troubles for Earth.
Right now the planet is enjoying a period of low activity called solar minimum. But particles have been building up inside the magnetosphere as the solar wind carries northward-facing field lines to Earth.
During the next solar cycle, the winds are expected to carry southward-facing field lines, which connect with the magnetosphere in such a way that they provide extra charge to any plasma inside the shield.
"You can sort of compare [the situation] to a gas stove," Raeder said.
"If you turn on the gas and you light it right away, nothing will happen—the gas stove will go on and there will be a flame.
"But if you turn on a gas stove and you don't do anything for a while and then you throw in a match, what will happen? It will say, Boom!"
Found this Post interesting? Receive new posts via RSS (What is RSS?) or subscribe via email at the top of this page...