SNN

Aurora alert: Possible geomagnetic storm could bring northern lights as far south as New York

Heightened solar activity has prompted the National Oceanic and Atmospheric Administration (NOAA) Space Weather Prediction Center to issue a geomagnetic storm watch for July 24.

The culprit? A plume of plasma and magnetic field known as a coronal mass ejection (CME) that was released from the sun on Jul 21 and is now barreling toward Earth and due to arrive on July 24.

CMEs carry with them electrically charged atoms known as ions, when CMEs collide with Earth’s magnetosphere they can trigger geomagnetic storms. During geomagnetic storms the ions collide with gases in Earth’s atmosphere and release energy in the form of light, we recognize this as the northern lights or aurora borealis in the Northern Hemisphere or the southern lights, or aurora australis in the Southern Hemisphere.

Geomagnetic storms are classified by NOAA using a G-scale to measure the intensity of geomagnetic storms. They range from G5, the most extreme class to G1 minor class storms. The recent geomagnetic storm watch issued by NOAA is currently classified as a G2-class.

Like weather on Earth, space weather is a fickle creature and difficult to predict. Geomagnetic storm warnings like this are not uncommon and in some cases, they fizzle to nothing. As we get closer to July 24 space weather forecasters will gain a better idea of when (if at all) to expect the CME to arrive.

A G2 Watch is in effect for 24 July due to the likely arrival of a halo CME that erupted on 21 July. (Image credit: NOAA Space Weather Prediction Center)

Though aurora chasers will be willing on the arrival of the CME and have everything crossed for a direct hit, this isn’t a sentiment shared by all.

CMEs can wreak havoc on our technological world and pose a threat to both satellites and astronauts in low Earth orbit. On Earth, CMEs can cause surges in electrical currents which can overload power grids, causing blackouts. They can also jostle Earth’s magnetic field and disrupt radio transmissions and increase radio static in Earth’s ionosphere.

In space, high-energy particles from the CME can damage satellites in low-Earth orbit. CMEs can also cause Earth’s atmosphere to warm and expand, as it does it creates a thicker medium through which a satellite must travel, the additional drag can slow a satellite’s momentum and lead to a lowering of its orbit.

Astronauts also receive a higher dose of radiation during a CME event compared to if they were on Earth, though they are still mostly protected by the magnetosphere and shielded by the structure of the spacecraft.

For the latest space weather alerts and forecast check out NOAA’s Space Weather Prediction Center. 

Exit mobile version