Scientists have suggested launching a giant ‘airbag’ into space to protect Earth from terrifying solar superstorms.
Our planet is regularly bombarded by coronal mass ejections (CMEs) — giant clouds of electrically charged plasma blasted into space by powerful explosions on the Sun.
These are responsible for beautiful aurora displays but, on occasion, can trigger radio blackouts and power outages.
Every few hundred years or so, the sun spits out a supercharged storm with the ability to cripple satellites, dose astronauts with lethal levels of radiation, damage power grids and even knock out the internet.
Experts have proposed a radical new way to combat this, which involves launching six bus-sized satellites into orbit at around 22,500 miles (36,000km) above Earth.
The next time a solar superstorm takes place, these would empty gas canisters around the edge of Earth’s magnetic field.
This would create a giant wall of plasma to cushion and redirect incoming particles – cutting the intensity of the storm in half.
‘The protection provided by (this) approach mimics an automobile airbag – installed once, ready to deploy at a moment’s notice and requiring little maintenance,’ the researchers said.
Experts have proposed launching six bus-sized satellites into orbit. The next time a solar superstorm takes place, these would empty gas canisters around the edge of Earth’s magnetic field, creating a giant wall of plasms to cushion and redirect incoming particles
Scientists have warned that a once-in-a-century solar storm could cause chaos on Earth, triggering power outages and radio blackouts
The team, from the University of Michigan, spelled out their proposal in the journal Space Weather.
‘While humans become more reliant on Earth’s space environment, the potential for significant harm from severe space weather continues to grow,’ they wrote.
‘As structures from the sun reach Earth’s magnetosphere and space environment, they deposit energy that fuels geomagnetic storms.
‘Currently, space weather researchers work to predict the timing and intensity of space weather events, often providing warnings of several days prior to the initiation of a strong geomagnetic storm.
‘Here a new paradigm is presented where, rather than prediction alone, active steps are taken to mitigate the impact of solar wind structures through temporarily modifying Earth’s magnetosphere.’
The idea behind the satellite constellation, called StormWall, is to create a protective barrier before an incoming solar storm arrives.
To do this, they would release a large quantity of a reactive gas such as sodium, barium, calcium or lithium into Earth’s magnetosphere when a large flare on the sun is detected.
This would then create a huge plasma barrier that would push back against the incoming bombardment of charged particles, and help divert it around our planet.
To test how effective this could be, they carried out simulations of a major geomagnetic storm that took place in May 2024 and found their proposed ‘airbag’ could have reduced the intensity of the resulting geomagnetic disturbance by as much as 84 per cent
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To test how effective this could be, they carried out simulations of a major geomagnetic storm that took place in May 2024.
This was the most powerful disturbance in 20 years.
Analysis revealed their proposed ‘airbag’ could have reduced the intensity of the resulting geomagnetic disturbance by as much as 84 per cent.
‘If I knew that a 100-year disturbance was coming and it would knock out power grids, I definitely would want this,’ David Sibeck, chief of heliophysics at NASA’s Goddard Space Flight Center, told Science magazine.
The study concludes: ‘This work has shown that humans have the ability and technology to actively stop or reduce the intensity of a geomagnetic storm.
‘The total mass required is within the ability of current and near-future launch technologies and the process lends itself well to international collaboration.
‘The threat of the space environment on human life and technology remains a major risk internationally.
‘Response thus far has been primarily based on developing prediction systems. Here, rather than prediction alone, a method is provided for defence.’
Earlier this year, a terrifying report laid bare exactly what would happen if a solar storm hit the UK.
In Britain’s worst–case scenario, an eruption of charged particles from the sun will smash into the atmosphere, triggering electrical blackouts and widespread disruption.
From the satellites that power GPS services to the sensitive electronics inside nuclear power stations, almost every type of electronic system would be at risk.
When this ‘geomagnetic storm’ is strong enough, it can induce electrical currents in any long stretches of metal on the surface – including the high–voltage wires that make up the grid.
The report warns that this would trigger safety switches in transformer stations, leading to cascading blackouts that would plunge the country into darkness.
Power surges could also affect train signals, leading to failures that could cause deadly collisions.
A strong enough solar storm might even change the orbits of some satellites, causing major problems for the world’s navigation systems.



