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Space
Space
Science
Daisy Dobrijevic

2 colossal solar flares explode from the sun and Earth is in the firing line (video)

Two image stills of solar flares erupting from the surface of the sun. The X-flare is on the left and the M-flare is on the right. .

Newly emerged sunspot region AR3663 is already making a name for itself, firing off not one but two powerful solar flares within just six hours of each other. 

The first eruption occurred last night (May 2) when the sun released the most powerful category flare, an X-class solar flare, causing shortwave radio blackouts across Australia, Japan and much of China. The flare peaked at 10:22 p.m. EDT (0222 GMT) and ended shortly after at 10:27 p.m. EDT (0227 GMT). The next eruption came this morning (May 3) when the second most powerful category flare, an M-class solar flare, peaked around 4:00 a.m. EDT (0800 GMT). 

The explosive sunspot was facing Earth at the time of both eruptions and it is possible that a coronal mass ejection (CME), a large expulsion of plasma and magnetic field, accompanied at least one of these solar flares. Shortly after the X-flare, the U.S. Air Force reported a Type II solar radio burst "a type of natural radio signal emitted by shocked gas at the leading edge of a CME," Spaceweather.com reported.

Related: NASA prepares for intense sun storms on Mars during solar maximum

Two image stills of solar flares erupting from the surface of the sun on May 3, 2024. The X-flare is on the left and the M-flare is on the right.  (Image credit: NASA / SDO and the AIA, EVE, and HMI science teams / helioviewer.org)

If a CME is Earth-directed it can wreak havoc with power grids, telecommunication networks and orbiting satellites, as well as expose astronauts to dangerous doses of radiation. But they are a welcomed visitor for skywatchers as they can trigger geomagnetic storms which in turn spark dynamic aurora displays visible at latitudes beyond their 'normal' polar range. 

You can stay tuned with the latest details concerning any Earth-directed components of the recent eruptions on the National Oceanic and Atmospheric Administration (NOAA) Space Weather Prediction Center's forecast discussion.

According to solar physicist Keith Strong, last night's X-flare was the 11th largest flare so far this cycle. 

"X FLARE! Sunspot region AR3663 just produced an X1.7 flare, the 11th largest flare so far this cycle. It was an impulsive flare lasting a total of about 25 minutes and peaking at 02:22 U.T," Strong posted on X.

Solar flares, eruptions from the sun's surface, emit intense bursts of electromagnetic radiation. They occur when magnetic energy accumulating in the solar atmosphere is subsequently released. Solar flares are categorized by size into lettered groups, with X-class being the most powerful. Then there are M-class flares that are 10 times less powerful than X-class flares, followed by C-class flares which are 10 times weaker than M-class flares, B-class are 10 times weaker than C-class flares and finally, A-class flares which are 10 times weaker than B-class flares and have no noticeable consequences on Earth

Within each class, numbers from 1-10 (and beyond for X-class flares) describe a flare's relative strength. Last night's flare clocked in at X1.69, according to Spaceweatherlive.com, measured by NASA's GOES-16 satellite, and this morning's flare peaked at M4.5. 

Shortwave radio blackouts like the one witnessed over Australia, Japan and much of China last night are common shortly after powerful solar flare eruptions due to the strong pulse of X-rays and extreme ultraviolet radiation emitted during these events. The radiation travels toward Earth at the speed of light and ionizes (gives an electrical charge to) the top of Earth's atmosphere when it reaches us.

Related: Watch 4 solar flares erupt from the sun at nearly the same time in extremely rare event (video)

Strong radio blackouts were observed over Japan, Australia and parts of China. (Image credit: NOAA/SWPC)

This ionization causes a higher-density environment for the high-frequency shortwave radio signals to navigate through in order to support communication over long distances. The radio waves that interact with electrons in the ionized layers lose energy due to more frequent collisions, and this can lead to radio signals becoming degraded or completely absorbed according to NOAA's Space Weather Prediction Center

Solar activity is ramping up as we approach solar maximum, the peak of solar activity during the sun's approximately 11-year solar cycle, indicated by the frequency of sunspots

Despite the large number of sunspots currently visible on the sun's surface, our star has been relatively quiet in recent weeks. 

But not anymore. 

Just a few days ago, on April 30, the sun unleashed a near X-class solar flare and with the recent X-class and M-class flare eruptions overnight, the sun is anything but quiet. 

Solar scientists are keeping a watchful eye on the sun as it approaches solar maximum because solar activity can have a significant influence on our lives here on Earth. 

Potent solar flares pose significant risks to spacecraft, satellites, and terrestrial technologies. By traveling at the speed of light, they don't give us a lot of notice before striking. To mitigate potential damage, organizations like NASA, NOAA, and the U.S. Air Force Weather Agency vigilantly track solar activity. 

"We can't ignore space weather, but we can take appropriate measures to protect ourselves," NASA says.

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