A New Kind of Solar Storm
Going to the Moon? Be careful. A new kind of solar storm can take you by surprise.
June 10, 2005: January 2005 was a stormy month--in space. With little warning, a giant spot materialized on the sun and started exploding. Between January 15th and 19th, sunspot 720 produced four powerful solar flares. When it exploded a fifth time on January 20th, onlookers were not surprised.
They should have been. Researchers realize now that the January 20th blast was something special. It has shaken the foundations of space weather theory and, possibly, changed the way astronauts are going to operate when they return to the Moon.
Sunspot 720 unleashed a new kind of solar storm.
"We've been hit by strong proton storms before, but [never so quickly]," says solar physicist Robert Lin of UC Berkeley. "Proton storms normally develop hours or even days after a flare." This one began in minutes.
Right: The Jan. 20th proton storm photographed from space by the Solar and Heliospheric Observatory (SOHO). The many speckles are solar protons striking the spacecraft's digital camera. [More]
Proton storms cause all kinds of problems. They interfere with ham radio communications. They zap satellites, causing short circuits and computer reboots. Worst of all, they can penetrate the skin of space suits and make astronauts feel sick.
"The last time we saw a storm like this was in February 1956." The details of that event are uncertain, though, because it happened before the Space Age. "There were no satellites watching the sun."
According to space weather theory--soon to be revised--this is how a proton storm develops:
It begins with an explosion, usually above a sunspot. Sunspots are places where strong magnetic fields poke through the surface of the Sun. For reasons no one completely understands, these fields can become unstable and explode, unleashing as much energy as 10 billion hydrogen bombs.
From Earth we see a flash of light and X-rays. This is the "solar flare," and it's the first sign that an explosion has occurred. Light from the flare reaches Earth in only 8 minutes.
Above: Sunspot 720 erupting on Jan. 15th, photographed by Jack Newton.
Next, if the explosion is powerful enough, a billion-ton cloud of gas billows away from the blast site. This is the coronal mass ejection or "CME." CMEs are relatively slow. Even the fastest ones, traveling one to two thousand km/s, take a day or so to reach Earth. You know a CME has just arrived when you see auroras in the sky.
En route to Earth, CMEs plow through a lot of gaseous material, first in the sun's atmosphere and then out in interplanetary space. You thought space was empty? No. The void between planets is filled with protons and other particles from the solar wind. Shock waves in front of the CME can accelerate these protons in our direction--hence the proton storm.
"CMEs can account for most proton storms," says Lin, but not the proton storm of January 20th. According to theory, CMEs can't push material to Earth quickly enough.
Back to the drawing board: If a CME didn't accelerate the protons, what did?
"We have an important clue," says Lin. When the explosion occurred, sunspot 720 was located at a special place on the sun: 60o west longitude. This means "the sunspot was magnetically connected to Earth."
Above: The sun's magnetic field spirals like water from a lawn sprinkler. The field line emerging from solar longitude 60 degrees west usually leads to Earth. [More]
"That's how the protons got here," speculates Lin. How they were accelerated, however, remains a mystery.
What does all this mean for astronauts? Stay inside when there's a big sunspot located near solar longitude 60o W. Or, if you must go moonwalking, take a radiation shelter with you. It's not as hard as it sounds.
Stay tuned for more on this topic in an upcoming Science@NASA story, "Radiation Shelters: Don't Leave Home Without One."
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