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What NASA Is Learning from the Biggest Geomagnetic Storm in 20 Years

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What NASA Is Learning from the Biggest Geomagnetic Storm in 20 Years

One year on, NASA scientists are still making huge discoveries about the largest geomagnetic storm to hit Earth in two decades, the Gannon storm. The findings are helping us better understand and prepare for the ways in which the Sun’s activity can affect us.

On May 10, 2024, the first G5 or “severe” geomagnetic storm in over two decades hit Earth. The event did not cause any catastrophic damages, but it did produce surprising effects on Earth. The storm, which has been called the best-documented geomagnetic storm in history, spread auroras to unusually low latitudes and produced effects spanning from the ground to near-Earth space. Data captured during this historic event will be analyzed for years to come, revealing new lessons about the nature of geomagnetic storms and how best to weather them. Credit: NASA/Joy Ng

One year ago today, representatives from NASA and about 30 other U.S. government agencies gathered for a special meeting to simulate and address a threat looming in space. The threat was not an asteroid or aliens, but our very own life-giving Sun.

The inaugural Space Weather Tabletop Exercise was supposed to be a training event, where experts could work through the real-time ramifications of a geomagnetic storm, a global disruption to Earth’s magnetic field. Driven by solar eruptions, geomagnetic storms can decimate satellites, overload electrical grids, and expose astronauts to dangerous radiation. Minimizing the impacts of such storms requires close coordination, and this meeting was their chance to practice.

Then, their simulation turned into reality.

“The plan was to run through a hypothetical scenario, finding where our existing processes worked and where they needed improvement,” said Jamie Favors, director of NASA’s Space Weather Program at NASA Headquarters in Washington. “But then our hypothetical scenario was interrupted by a very real one.”

On May 10, 2024, the first G5 or “severe” geomagnetic storm in over two decades hit Earth. The event, named the Gannon storm in memory of leading space weather physicist Jennifer Gannon, did not cause any catastrophic damages. But a year on, key insights from the Gannon storm are helping us understand and prepare for future geomagnetic storms.

A detailed, fiery image of the Sun showing bright solar flares and textured surface, with a small inset at the bottom right comparing the tiny size of Earth to the massive scale of the Sun.
NASA’s Solar Dynamics Observatory captured this image of the Sun on May 7, 2024, in extreme ultraviolet light (at a wavelength of 304 Ångstroms). At center, the active region that instigated the Gannon storm stretches approximately 17 times the size of Earth. (A scaled image of Earth is inset for size reference.) In early May 2024, the active region released a chain of powerful solar eruptions, including several coronal mass ejections, or CMEs — giant clouds of solar particles — that merged to form a superstorm that reached Earth on May 10. Ahead of the storm, the National Oceanic and Atmospheric Administration, or NOAA, issued its first severe geomagnetic storm watch in almost two decades.
NASA/Helioviewer

Storm Consequences

The Gannon storm had effects on and off our planet.

On the ground, some high-voltage lines tripped, transformers overheated, and GPS-guided tractors veered off-course in the Midwestern U.S., further disrupting planting that had already been delayed by heavy rains that spring.

A green tractor with yellow wheels pulls a red trailer across a flat, dirt-covered field with some trees, a field of green plants, and a partly cloudy sky in the background.
Some modern tractors use GPS to help farmers plant efficiently and maximize crop yields. During the Gannon storm in May 2024, however, certain GPS-guided tractor models veered off course or stopped working, disrupting or delaying planting for many U.S. farmers.
Storyblocks

“Not all farms were affected, but those that were lost on average about $17,000 per farm,” said Terry Griffin, a professor of Agricultural Economics at Kansas State University. “It’s not catastrophic, but they’ll miss it.”

In the air, the threat of higher radiation exposure, as well as communication and navigation losses, forced trans-Atlantic flights to change course.


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May 11, 2024
May 18, 2024

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May 11, 2024

May 18, 2024

Before and After

Trans-Atlantic Flights Rerouted during Gannon Storm

May 11, 2024 – May 18, 2024


During the Gannon storm on May 10 and 11, 2024, many trans-Atlantic flights took more southerly routes across the ocean to avoid the risk of higher radiation for passengers and crew, as well as to avoid potential communication and navigation losses closer to the North Pole. The first image shows a snapshot of flight patterns on May 11, 2024, at 3:30 UTC (11:30 p.m. EDT on May 10) during the Gannon storm, when flights were redirected to more southern routes. The second image shows the flight patterns one week later, on May 18, 2024, at 3:30 UTC as flights followed their typical route. Credit: Flightradar24

During the storm, Earth’s upper atmospheric layer called the thermosphere heated to unusually high temperatures. At 100 miles altitude, the temperature typically peaks at 1,200 degrees Fahrenheit, but during the storm it surpassed 2,100 degrees Fahrenheit. NASA’s GOLD (Global-scale Observations of the Limb and Disk) mission observed the atmosphere expanding from the heat to create a strong wind that lofted heavy nitrogen particles higher.

A circular heatmap shows a swirling pattern of colors, with red and yellow regions indicating higher values, and blue and green areas showing lower values. The overlay covers the Atlantic Ocean and parts of surrounding continents.
The unique swirls in this image of GOLD data, show the ratio of lighter oxygen to nitrogen — a key atmospheric indicator — that exhibited a previously unseen structure in Earth’s thermosphere.
Evans et al. 2024

In orbit, the expanded atmosphere increased drag on thousands of satellites. NASA’s ICESat-2 lost altitude and entered safe mode while NASA’s Colorado Inner Radiation Belt Experiment (CIRBE) CubeSat deorbited prematurely five months after the storm. Others, such as the European Space Agency’s Sentinel mission, required more power to maintain their orbits and perform maneuvers to avoid collisions with space debris.

The storm also dramatically changed the structure of an atmospheric layer called the ionosphere. A dense zone of the ionosphere that normally covers the equator at night dipped toward the South Pole in a check mark shape, causing a temporary gap near the equator.

The Gannon storm also rocked Earth’s magnetosphere, the magnetic bubble surrounding the planet. Data from NASA missions MMS (Magnetospheric Multiscale) and THEMIS-ARTEMIS — short for Time History of Events and Macroscale Interactions-Acceleration, Reconnection, Turbulence and Electrodynamics of the Moon’s Interaction with the Sun — saw giant, curling waves of particles and rolled-up magnetic fields along the edge of the CMEs. These waves were perfectly sized to periodically dump extra magnetic energy and mass into the magnetosphere upon impact, creating the largest electrical current seen in the magnetosphere in 20 years.

Incoming energy and particles from the Sun also created two new temporary belts of energetic particles within the magnetosphere. Discovered by CIRBE, these belts formed between the Van Allen radiation belts that permanently surround Earth. The belt’s discovery is important to spacecraft and astronauts that can be imperiled by high-energy electrons and protons in the belts.

Illustration of Earth surrounded by colorful, concentric rings representing the Van Allen radiation belts, with white magnetic field lines arching around the planet against a black space background.
The Gannon storm created two extra radiation belts, sandwiched between the two permanent Van Allen Belts. One of the new belts, shown in purple, included a population of protons, giving it a unique composition that hadn’t been seen before. The discovery of the new belts is particularly important for protecting spacecraft launching into geostationary orbits, since they travel through the Van Allen Belts several times before reaching their final orbit.
NASA/Goddard Space Flight Center/Kristen Perrin

Unusual Auroras

The storm also ignited auroras around the globe, including places where these celestial light shows are rare. NASA’s Aurorasaurus project was flooded with more than 6,000 observer reports from over 55 countries and all seven continents.

Photographers helped scientists understand why auroras observed throughout Japan were magenta rather than the typical red. Researchers studied hundreds of photos and found the auroras were surprisingly high — around 600 miles above the ground (200 miles higher than red auroras typically appear).

A torii gate stands by the shore with a small hill in the background, under a night sky filled with stars, a bright moon, and vivid purple and pink auroras.
In Japan, where it’s typical to see red auroras, numerous skywatchers captured photos of unusual magenta auroras instead. With the help of hundreds of photos like this one shared via social media, researchers found the magenta auroras were exceptionally high — around 600 miles above the ground (compared to a typical maximum height of 400 miles for red auroras, which are usually the highest).
KAGAYA

In a paper published in the journal Scientific Reports, the research team says the peculiar color likely resulted from a mix of red and blue auroras, produced by oxygen and nitrogen molecules lofted higher than usual as the Gannon storm heated and expanded the upper atmosphere.

“It typically needs some special circumstances, like we saw last May,” co-author Josh Pettit of NASA’s Goddard Space Flight Center said of Japan’s magenta auroras. “A very unique event indeed.”


Learn how auroras form and why they have different colors

Otherworldly Effects

Impacts of the Sun’s amped-up solar activity didn’t end at Earth. The solar active region that sparked the Gannon storm eventually rotated away from our planet and redirected its outbursts toward Mars.

As energetic particles from the Sun struck the Martian atmosphere, NASA’s MAVEN (Mars Atmosphere and Volatile Evolution) orbiter watched auroras engulf the Red Planet from May 14 to 20.

An animated gif of Mars, appearing in grayscale, with a pixellated pattern of purple and white lights shimmering on the left half of the planet, indicating auroras detected by NASA's MAVEN spacecraft.
The purple color in this animated GIF shows auroras across Mars’ nightside as detected by the Imaging Ultraviolet Spectrograph instrument aboard NASA’s MAVEN (Mars Atmosphere and Volatile EvolutioN) orbiter. The brighter the purple, the more auroras were present. MAVEN took these images between May 14 and 20, 2024, as energetic particles from a solar storm were arriving at Mars. The sequence pauses at the end, when the most energetic particles arrived and overwhelmed the instrument with noise. MAVEN made the observations as it orbited below Mars, looking up at the nightside of the planet. (Mars’ south pole can be seen on the right, in full sunlight.)
NASA/University of Colorado/LASP

Solar particles overwhelmed the star camera on NASA’s 2001 Mars Odyssey orbiter (which uses stars to orient the spacecraft), causing the camera to cut out for almost an hour.

On the Martian surface, images from the navigation cameras on NASA’s Curiosity rover were freckled with “snow” — streaks and specks caused by charged particles. Meanwhile, Curiosity’s Radiation Assessment Detector recorded the biggest surge of radiation since the rover landed in 2012. If astronauts had been there, they would have received a radiation dose of 8,100 micrograys — equivalent to 30 chest X-rays.


Read more about the effects on Mars

A black-and-white photo of a rocky Martian landscape, featuring a large sloped hill with visible layers on the right and a smaller peak in the distance under a hazy sky. Specks of white appear to dot the image from time to time, a response to solar energetic particles from the Sun hitting the camera.
The specks in this image sequence were caused by charged particles from the Sun hitting one of the navigation cameras aboard NASA’s Curiosity Mars rover on May 20, 2024. The sequence also shows the effects of a wind gust that happened to occur at the same time on the Martian surface.
NASA/JPL-Caltech

Still More to Come

The Gannon storm spread auroras to unusually low latitudes and has been called the best-documented geomagnetic storm in history. A year on, we have just begun unraveling its story. Data captured during this historic event will be analyzed for years to come, revealing new lessons about the nature of geomagnetic storms and how best to weather them.

By Mara Johnson-Groh, Miles Hatfield, and Vanessa Thomas
NASA’s Goddard Space Flight Center, Greenbelt, Md.

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      Arrival & Departure
      The SpaceX Dragon spacecraft will arrive at the space station and dock autonomously to the forward port of the station’s Harmony module at approximately 7:30 a.m. on Monday, Aug. 25. NASA astronauts Mike Fincke and Jonny Kim will monitor the spacecraft’s arrival. It will stay docked to the orbiting laboratory for about four months before splashing down and returning critical science and hardware to teams on Earth.
      NASA astronauts Mike Fincke and Jonny Kim will monitor the arrival of the SpaceX Dragon cargo spacecraft from the International Space Station.NASA Research Highlights
      Preventing bone loss in space
      Microgravity Associated Bone Loss-B (MABL-B) assesses the effects of microgravity on bone marrow stem cells and may provide a better understanding of the basic molecular mechanisms of bone loss that occurs during spaceflight and from normal aging on Earth.NASA A study of bone-forming stem cells in microgravity could provide insight into the basic mechanisms of the bone loss astronauts experience during long-duration space flight ahead of future exploration of the Moon and Mars.
      Researchers identified a protein in the body called IL-6 that can send signals to stem cells to promote either bone formation or bone loss. This work evaluates whether blocking IL-6 signals could reduce bone loss during spaceflight. Results could improve our understanding of bone loss on Earth due to aging or disease and lead to new prevention and treatment strategies.
      Printing parts, tools in space
      Printing parts, tools in space
      The objective of the Metal 3D printer aboard the International Space Station is to gain experience with operating and evaluating the manufacturing of spare parts in microgravity to support long duration space missions.NASA As mission duration and distance from Earth increase, resupply becomes harder. Additive manufacturing, or 3D printing, could be used to make parts and dedicated tools on demand, enhancing mission autonomy.
      Research aboard the space station has made strides in 3D printing with plastic, but it is not suitable for all uses. Investigations from ESA’s (European Space Agency) Metal 3D Printer builds on recent successful printing of the first metal parts in space.
      Bioprinting tissue in microgravity
      Maturation of Vascularized Liver Tissue Construct in Zero Gravity (MVP Cell-07) is a biotechnology experiment studying bioprinted, or lab grown, liver tissues complete with blood vessels in space. The results could improve astronaut health on long missions and lead to new ways to treat patients on Earth.NASA Researchers plan to bioprint liver tissue containing blood vessels on the ground and examine how the tissue develops in microgravity. Results could help support the eventual production of entire functional organs for transplantation on Earth.
      A previous mission tested whether this bioprinted liver tissue survived and functioned in space. This experimental round could show whether microgravity improves the development of the bioprinted tissue.
      Biomanufacturing drug-delivery medical devices
      The InSPA-Auxilium Bioprinter will test 3D printing medical implant devices designed to deliver drugs and treat various health conditions such as nerve inuries. Printing on the International Space Station may produce higher-quality devices than on Earth.NASA Scientists are creating an implantable device in microgravity that could support nerve regrowth after injuries. The device is created through bioprinting, a type of 3D printing that uses living cells or proteins as raw materials.
      Traumatic injuries can create gaps between nerves, and existing treatments have a limited ability to restore nerve function and may result in impaired physical function. A bioprinted device to bridge nerve gaps could accelerate recovery and preserve function.
      Cargo Highlights
      NASA’s SpaceX 33rd commercial resupply mission will carry over 5,000 pounds of cargo to the International Space Station.NASA Hardware
      Launch:
      Reboost Kit – This kit will perform a reboost demonstration of the station to maintain its current altitude. The hardware, located in Dragon’s trunk, contains an independent propellant system, separate from the spacecraft’s main system, to fuel two Draco engines using existing hardware and propellant system design. The boost kit will demonstrate the capability to maintain the orbiting lab’s altitude starting in September with a series of burns planned periodically throughout the fall of 2025. During NASA’s SpaceX 31st commercial resupply services mission, the Dragon spacecraft first demonstrated these capabilities on Nov. 8, 2024. Poly Exercise Rope Kit – These exercise ropes distribute the desired exercise loads through a series of pulleys for the Advanced Restrictive Exercise Device. The ropes have a limited life cycle, and it will be necessary to replace them once they have reached their limit. Brine Filter – These filters remove solid particles from liquid in urine during processing as a part of the station’s water recovery system. Acoustic Monitor – A monitor that measures sound and records the data for download. This monitor will replace the sound level meter and the acoustic dosimeter currently aboard the orbiting laboratory. Multi-filtration Bed – This space unit will support the Water Processor Assembly and continue the International Space Station Program’s effort to replace a fleet of degraded units aboard the station to improve water quality through a single bed. Water Separator Orbital Unit – The unit draws air and condensate mixture from a condensing heat exchanger and separates the two components. The air is returned to the cabin air assembly outlet air-flow stream, and the water is delivered to the condensate bus. This unit launches to maintain in-orbit sparing while another is being returned for repair. Anomaly Gas Analyzer Top Assembly – This battery-powered device detects and monitors gases aboard the station, including oxygen, carbon dioxide, hydrogen chloride, hydrogen fluoride, ammonia, carbon monoxide, and hydrogen cyanide. It also measures cabin pressure, humidity, and temperature. It replaces the Compound Specific Analyzer Combustion Products as the primary tool for detecting airborne chemicals and conditions. Separator Pump (Water Recovery and Management) – This electrically-powered pump separates liquids and gases while rotating. It includes a scoop pump that moves the separated liquid into storage containers for use in other systems. The pump also contains sensor components and a filter to reduce electrical interference from the motor. Launching to maintain in-orbit sparing. Reducer Cylinder Assembly & Emergency Portable Breathing Apparatus – Together, this hardware provides 15 minutes of oxygen to a crew member in case of an emergency (smoke, fire, alarm). Two are launching to maintain a minimum in-orbit spare requirement.  Passive Separator Flight Experiment – This experiment will test a new method for separating urine and air using existing technology that combines a water-repellent urine hose with an airflow separator from the station’s existing Waste Hygiene Compartment. Improved Resupply Water Tanks – Two tanks, each holding approximately 160 pounds of potable water, to supplement the Urine Processing Assembly. NORS (Nitrogen/Oxygen Recharge System) Maintenance Tank/Recharge Tank Assembly, Nitrogen – The NORS maintenance kit comprises two assemblies: the NORS recharge tank assembly and the NORS vehicle interface assembly. The recharge tank assembly will be pressurized with nitrogen gas for launch. The vehicle interface assembly will protect the recharge tank assembly for launch and stowage aboard the space station. Launching to maintain reserve oxygen levels on station. Swab Kits – These quick-disconnect cleaning kits are designed and created to replace in-orbit inventory. Return:
      Oxygen Generation Assembly Pump – The assembly pump converts potable water from the water recovery system into oxygen and hydrogen. The oxygen is sent to the crew cabin, and the hydrogen is either vented or used to produce more water. The International Space Station has been using this process to produce oxygen and hydrogen for 15 years, and this unit will be retired upon its return to Earth. The flight support equipment within will be refurbished and used in a new pump launched aboard a future flight. Carbon Dioxide Monitoring Assembly – A carbon dioxide monitor that measures the gas using the infrared absorption sensor. It expired in July 2025 and will return for refurbishment. Meteoroid Debris Cover Center Section Assembly – This external multilayer insulation provides thermal and micro-meteoroid orbital debris protection on the node port. After it is removed and replaced with a new assembly launching on NASA’s Northrop Grumman 23rd commercial resupply services mission, this unit will return for repair or used for spare parts.   Multi-filtration Bed – This spare unit supports the Water Processor Assembly, which improves water quality aboard the International Space Station. Its return is part of an ongoing effort to replace a degraded fleet of in-orbit units. After its use, this multi-filtration bed will be refurbished for future re-flight. Separator Pump – This electrically powered pump separates liquids and gases while rotating. It includes a scoop pump that moves the separated liquid into storage containers for use in other systems. The pump also contains sensor components and a filter to reduce electrical interference from the motor. This unit is designed to run to failure, and after investigation and testing, it will be returned for repair and future flight. Rate Gyro Enclosure Assembly – The Rate Gyro Assembly determines the space station’s rate of angular motion. It is returning for repair and refurbishment and will be used as a spare. NORS (Nitrogen/Oxygen Recharge System) Maintenance Kit (Oxygen) – The NORS Maintenance Kit comprises two assemblies: the NORS Recharge Tank Assembly and the NORS Vehicle Interface Assembly. The recharge tank assembly will be pressurized with Nitrogen gas for launch. The vehicle interface assembly will protect the recharge tank assembly for launch and stowage aboard the space station. They are routinely returned for reuse and re-flight. The kit also includes a VIA bag (vehicle interface assembly) with foam, which is used as a cargo transfer bag for launch and return to protect the tank. Watch, Engage
      Watch agency launch and arrival coverage on NASA+, Netflix, Amazon Prime, and more. Learn how to watch NASA content through a variety of platforms, including social media.
      NASA’s live launch coverage will begin at 2:25 a.m. on Aug 24. Dragon’s arrival coverage will begin at 6 a.m. on Aug. 25.
      Read more about how to watch and engage.

      View the full article

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