Dazzling auroras are just a warm-up as more solar storms are likely, scientists say
Nature talks to physicists about what to expect in the next months and beyond as the Sun hits its 'maximum'
Stunning photographs of the northern and southern lights, seen at much lower latitudes than usual, saturated social media on Friday and Saturday. For space-weather scientists, the auroras, created by a raging solar storm, were long-expected but dramatic evidence that the Sun is nearing the peak of its 11-year cycle of activity.
Satellite operators, electrical-grid managers and others who maintain crucial technological infrastructure are still assessing the impacts of this historic event — the severest geomagnetic storm since 2003. But most major systems seem to have weathered the blast.
That’s encouraging, because more storms are likely: the most powerful geomagnetic storms of a solar cycle can occur after the ‘solar maximum’, which is expected later this year. Nature explains what happened over the past few days and what solar physicists are anticipating next.
Why is this happening now?
The immediate cause is a cluster of sunspots, known as active region 3664, that appeared below the Sun’s equator on the side currently facing Earth. The cluster is around 17 times as wide as Earth, and is probably the largest and most complex sunspot region observed during the current solar cycle, which began in 2019, says Shawn Dahl, a space-weather forecaster at the US National Oceanic and Atmospheric Administration’s Space Weather Prediction Center in Boulder, Colorado.
Starting around 8 May, active region 3664 sent at least seven blasts of magnetized plasma, or coronal mass ejections, racing in Earth’s direction at speeds of up to 1,800 kilometres per second. Along with waves of charged particles and other solar debris, the coronal mass ejections swamped space-weather detectors. The experience was “hypnotic”, says solar physicist Ryan French of the National Solar Observatory in Boulder — first in watching the data flood in, and then later with the “raw awe” of witnessing the aurora.
How big was this storm?
Huge — by a number of measures. It was ‘extreme’ on the five-tiered scale that describes geomagnetic storms, and a ‘superstorm’ according to an index of changes in Earth’s magnetic field.
And then there were the auroras. Earth’s magnetic field shields humans and other life from the effects of solar storms by redirecting harmful particles around the planet. But when the material from coronal mass ejections slams into the magnetic field, it dumps energy into Earth’s upper atmosphere. Chemical elements there, such as oxygen and nitrogen, become ionized and glow in various colours, creating auroras. The lights are usually seen near Earth’s poles, but on 10 May, because of the intensity of the solar storm, auroras were seen at remarkably low latitudes, including in Mexico.
“Unforgettable,” says Steph Yardley, a space physicist at Northumbria University in Newcastle-upon-Tyne, UK. The auroras were so active that she had to look south, rather than north, from her viewing point in Scotland to see it.
What impacts did it have?
The solar storm interrupted radio and GPS communications across the globe. The broadband internet connection provided by Starlink, a division of the aerospace firm SpaceX — a service that relies on more than 5,000 satellites — reported some temporary degradation in the quality of its signals. That could be because of communications disruptions or because the storm changed the density of Earth’s atmosphere and created drag on the satellites, space-weather physicist Tamitha Skov posted on the social-media platform X (formerly Twitter).
In anticipation of the extreme solar activity, electrical-grid operators had taken protective measures — geomagnetic storms can induce extra electrical currents in the grid, causing power cuts. New Zealand’s electrical-transmission service temporarily turned off some circuits around the country to prevent equipment damage.
NASA said on 10 May that it foresaw no threat to the four US and three Russian astronauts aboard the International Space Station. Three people are aboard China's Tiangong space station, but there have been no reports of precautionary actions taken there either.
Some satellites did stop making scientific observations. For instance, NASA’s Chandra X-ray Observatory temporarily ceased gathering astronomical data as a precaution before the storm and stowed its instruments to protect them from radiation blasts. And during the storm, NASA's ice-measuring ICESat-2 satellite automatically stopped doing science when it experienced unexpected rotation, most likely from increased atmospheric drag, an agency spokeswoman said.
What else can scientists learn from the storm?
There might be fresh insights to come. The European Space Agency’s Solar Orbiter probe is nearly behind the Sun with respect to Earth, giving it a different view of the storm. Active region 3664 is now rotating off of the side of the Sun seen from Earth and into the field of view of Solar Orbiter. “We should get a better idea in the next few days if this sunspot intends to keep packing the punches on the other side of the Sun,” says David Williams, the spacecraft’s instrument operations scientist. NASA’s Parker Solar Probe — which is in the middle of a series of dives through the Sun’s outer atmosphere — happens to be at the outermost part of its looping orbit around the Sun and could be able to provide an extra perspective, but the data might take some time to reach Earth.
Researchers expect a coronal mass ejection to slam into Mars in the next few days, says Shannon Curry, a planetary scientist at the University of Colorado in Boulder. That collision could be observed by NASA’s MAVEN spacecraft, which is orbiting the red planet.
When could the next big storm affect Earth?
At any time. Scientists expect the current solar cycle to peak some time this year, owing to the number of sunspots they are observing. The biggest storms typically happen months to years after this official peak. Furthermore, as the solar cycle progresses, sunspots tend to appear closer to the Sun’s equator, increasing the chances of coronal mass ejections that will head directly for Earth rather than out into space, Dahl says.
doi: https://doi.org/10.1038/d41586-024-01432-7
This story originally appeared on: Nature - Author:Alexandra Witze