Giant eruptions from the Sun
By Nancy Crooker
Should a modern Joshua stop the moon in its tracks during a total solar eclipse so that for hours on end we could watch the hazy corona surrounding the Sun, we would see an amazing phenomenon called a "coronal mass ejection"-CME, for short. We would see a huge bubble of coronal material form and then leave the Sun, heading out into space. We would have witnessed the birth of a space storm.
CMEs were recognized as a common solar phenomenon in the 1970s when a technological Joshua called a "coronagraph" flying on an orbiting laboratory called "Skylab" held an artificial moon fixed in front of the Sun and inaugurated an era of routine CME observations. A coronagraph simulates a total solar eclipse by blocking the bright light from the Sun with a disk. To see CMEs, a coronagraph must be above the atmosphere, where the sky is black, as it is at ground level during a solar eclipse, so that the bright blue light of the atmosphere does not drown out the light from the CMEs.
Since routine CME observations began, it has taken scientists years more of research to establish that CMEs produce space storms, and to significantly improve means of predicting them. Understanding and predicting space storms is important to society because of our rapidly increasing dependence upon technology that space storms affect. Space storms can cripple satellites, interrupt communications systems, and cause power failures. We now understand that the key storm ingredient in a CME is its magnetic field, which is coiled inside it like a slinky. To appreciate why coiled magnetic fields bring stormy space weather, one needs to know something about fair weather in space-namely, the background flow called the "solar wind" and the configuration of its imbedded magnetic fields.
Interplanetary space is filled with the solar wind, the Sun's expanding atmosphere of high-speed charged particles, which sets the fair weather backdrop for CMEs. Unlike weather on Earth, however, the important parameter is not the wind itself but its imbedded magnetic field, which comes from the Sun. Eugene Parker (Univ. of Chicago), the scientist who predicted the existence of the solar wind, recognized that the solar wind would draw the solar field out into space as if it were frozen to the flow. Further, he deduced that in the ecliptic plane (that is, the plane in which the planets rotate about the Sun), the Sun's rotation about its own axis would cause the field lines to radiate away from the Sun in a spiral pattern like water from a rotating garden sprinkler. Subsequent spacecraft observations have proven Parker correct.
For Earth, the gently spiraling magnetic fields carried by the solar wind herald fair weather because Earth's magnetic shield, the magnetosphere, deflects them. The magnetosphere is a tadpole-shaped obstacle in the solar wind created by Earth's magnetic field. At the head of the tadpole, where it faces into the wind, Earth's magnetic field points northward, perpendicular to the spiral field. Fields perpendicular to each other, for the most part, slip past each other. Antiparallel fields, on the other hand, connect when they meet. Thus any southward pointing fields in the solar wind link with Earth's field, and like newly connected pipes, allow solar wind particles and energy to pour into the magnetosphere. The magnetosphere's response is a geomagnetic storm, complete with auroral displays and potential problems for satellites, power grids, and radio transmission. What heralds bad space weather for Earth, then, are southward fields in the solar wind-and the stronger they are, the worse the storm.
What turns CMEs into space storms, then, is their strong, coiled fields, which nearly guarantee some portions pointing southward. Moreover, for those CMEs that travel faster than the background wind, the background fields ahead of them become strong through compression, strengthening any southward fluctuations there.
Viewed from the front, a CME in a coronagraph looks like a uniform halo around the disk blocking the Sun, hence the name, "halo CME." Halo CMEs have been difficult to detect because they are not as bright as CMEs viewed from the side. However, recent technological advances have made them routinely detectable with the coronagraph on the SOHO spacecraft. This ability will be a boon for space weather predictions. In a retrospective study of data from December 1996 to June 1997, nine halo CMEs were detected, and all nine produced geomagnetic storms. Only three additional storms occurred which could not be associated with halo CMEs.
This strong correspondence is remarkable in view of past prediction capabilities. Traditionally solar flares have been used to predict storms, and the failure rate has been high. Flares are brightening events on the Sun primarily at wavelengths shorter than visible light. Viewed in x-rays, for example, flares make the Sun look like a constantly sparkling jewel because they occur so frequently. The brightest flares have been used for storm predictions, and these often do accompany CMEs; hence their predictive capability. But many CMEs occur with no apparent associated flares or with flares so weak that they go undetected in standard monitoring techniques. Now that we can see the CMEs themselves, there is no need to depend upon such an unreliable predictor as a flare.
From an ethereal sight to a source of technological problems, CMEs continue to fascinate scientists. How they form, why they occur, and what makes some of them very fast are walls in our understanding that have yet to come tumbling down.
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