The cracks were detected before but researchers now know they can remain open for long periods, rather than opening and closing for just very brief intervals. This new discovery about how the Earth's magnetic shield is breached is expected to help space physicists give better estimates of the effects of severe space weather.These animations follow the solar wind as it emanates from the Sun to the Earth's Magnetic field (represented by red lines in the images). Where the solar wind's magnetic polarity is opposite that of the Earth's magnetic field, some electrically charged particles of the solar wind enter the Earth's magnetosphere through a crack formed during the interconnection of the Sun and Earth's magnetic field lines. The formation of the crack is represented by the white area in the first image. These particles flow like a waterfall down the field line and splash on the ionosphere creating a spot in the ultraviolet proton aurora about the size of California. Click on images for movies (1.7 meg & 1 meg). Click link for more movies & images. Credit: NASA
"We discovered that our magnetic shield is drafty, like a house with a window stuck open during a storm," said Dr. Harald Frey of the University of California, Berkeley, lead author of a paper on this research published Dec. 4 in Nature. "The house deflects most of the storm, but the couch is ruined. Similarly, our magnetic shield takes the brunt of space storms, but some energy continually slips through its cracks, sometimes enough to cause problems with satellites, radio communication, and power systems."
"The new knowledge that the cracks are open for long periods, instead of opening and closing sporadically, can be incorporated into our space weather forecasting computer models to more accurately predict how our space weather is influenced by violent events on the Sun," said Dr. Tai Phan, also of UC Berkeley, co-author of the Nature paper.What is the whole story here? Watch this reporter package about Wednesday's press conference (7 meg) by clicking on the left image. To the right: data from NASA's IMAGE spacecraft shows a spot the ultraviolet proton aurora (blue ring) created as solar material falls through crack in magnetosphere onto Earth's Ionosphere. The spot in the proton aurora is the bright blue section in the bottom half of the blue ring (the spot is circled in the animation). Click link for more movies & images. Credit: NASA
The solar wind is a stream of electrically charged particles (electrons and ions) blown constantly from the Sun. The solar wind transfers energy from the Sun to the Earth through the magnetic fields it carries and its high speed (hundreds of miles/kilometers per second). It can get gusty during violent solar events, like Coronal Mass Ejections (CMEs), which can shoot a billion tons of electrified gas into space at millions of miles per hour.
Earth has a magnetic field that extends into space for tens of thousands of miles, surrounding the planet and forming a protective barrier to the particles and snarled magnetic fields the Sun blasts toward it during CMEs. However, space storms and their vivid effects, like the aurora, which light up the sky over the polar regions with more than a hundred million watts of power, indicated that the shield was not impenetrable.
In 1961, Dr. Jim Dungey of the Imperial College, United Kingdom, predicted that cracks might form in the magnetic shield when the solar wind contained a magnetic field that was oriented in the opposite direction to a portion of the Earth's field. In these regions, the two magnetic fields would interconnect through a process known as "magnetic reconnection," forming a crack in the shield through which the electrically charged particles of the solar wind could flow. In 1979, Dr. Goetz Paschmann, of the Max Planck Institute for Extraterrestrial Physics, Germany, detected the cracks using the International Sun Earth Explorer (ISEE) spacecraft. However, since this spacecraft only briefly passed through the cracks during its orbit, it was unknown if the cracks were temporary features or if they were stable for long periods.
In the new observations, the Imager for Magnetopause to Aurora Global Exploration (IMAGE) satellite revealed an area almost the size of California in the arctic upper atmosphere (ionosphere) where a 75-megawatt "proton" aurora flared for hours. This aurora was different from the visible aurora known as the Northern and Southern lights. It was generated by heavy particles (ions) hitting the upper atmosphere and causing it to emit ultraviolet light, which is invisible to the human eye but detectable by the Far Ultraviolet Imager on IMAGE.
While the aurora was being recorded by IMAGE, the 4-satellite Cluster constellation flew far above IMAGE, directly through the crack, and detected solar wind ions streaming through. Normally, these solar wind ions would be deflected by Earth's shield, so Cluster's observation showed a crack was present. This stream of solar wind ions bombarded our atmosphere in precisely the same region where IMAGE saw the proton aurora. The fact that IMAGE was able to view the proton aurora for more than 9 hours, until IMAGE progressed in its orbit to where it could not observe the aurora, implies that the crack remained continuously open. Estimating from the IMAGE and Cluster data, the crack was twice the size of the Earth at the boundary of our magnetic shield, about 38,000 miles (60,000 km) above the planet's surface. Since the magnetic field converges as it enters the Earth in the polar regions, the crack narrowed to about the size of California down near the upper atmosphere.
IMAGE is a NASA satellite launched March 25, 2000 to provide a global view of the space around Earth influenced by the Earth's magnetic field. The Cluster satellites, built by the European Space Agency and launched July 16, 2000, are making a three-dimensional map of the Earth's magnetic field.
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