The sun, Earth, and many other planets are surrounded by giant magnetic bubbles.
Space may seem empty, but itβs actually a dynamic place, dominated by invisible forces, including those created by magnetic fields. Β Magnetospheres β the areas around planets and stars dominated by their magnetic fields β are found throughout our solar system. They deflect high-energy, charged particles called cosmic rays that are mostly spewed out by the sun, but can also come from interstellar space. Along with atmospheres, they help protect the planetsβ surfaces from this harmful radiation.
Itβs possible that Earthβs protective magnetosphere was essential for the development of conditions friendly to life, so finding magnetospheres around other planets is a big step toward determining if they could support life.
But not all magnetospheres are created equal β even in our own backyard, not all planets in our solar system have a magnetic field, and the ones we have observed are all surprisingly different.
Earthβs magnetosphere is created by the constantly moving molten metal inside Earth. This invisible βforce fieldβ around our planet has an ice cream cone-like shape, with a rounded front and a long, trailing tail that faces away from the sun. The magnetosphere is shaped that way because of the constant pressure from the solar wind and magnetic fields on the sun-facing side.
Earthβs magnetosphere deflects most charged particles away from our planet β but some do become trapped in the magnetic field and create auroras when they rain down into the atmosphere.
Mercury, with a substantial iron-rich core, has a magnetic field that is only about 1% as strong as Earthβs. It is thought that the planetβs magnetosphere is stifled by the intense solar wind, limiting its strength, although even without this effect, it still would not be as strong as Earthβs. The MESSENGER satellite orbited Mercury from 2011 to 2015, helping us understand our tiny terrestrial neighbor.
After theΒ sun, Jupiter has by far the biggest magnetosphere in our solar system β it stretches about 12 million miles from east to west, almost 15 times the width of the sun. (Earthβs, on the other hand, could easily fit inside the sun.) Jupiter does not have a molten metal core like Earth; instead, its magnetic field is created by a core of compressed liquid metallic hydrogen.
One of Jupiterβs moons, Io, has intense volcanic activity that spews particles into Jupiterβs magnetosphere. These particles create intense radiation belts and the large auroras around Jupiterβs poles.
Ganymede, Jupiterβs largest moon, also has its own magnetic field and magnetosphere β making it the only moon with one. Its weak field, nestled in Jupiterβs enormous shell, scarcely ruffles the planetβs magnetic field.
Our Juno mission orbits inside the Jovian magnetosphere sending back observations so we can better understand this region. Previous observations have been received from Pioneers 10 and 11, Voyagers 1 and 2, Ulysses, Galileo and Cassini in their flybys and orbits around Jupiter.
Saturnβs moon Enceladus transforms the shape of its magnetosphere. Active geysers on the moonβs south pole eject oxygen and water molecules into the space around the planet. These particles, much like Ioβs volcanic emissions at Jupiter, generate the auroras around the planetβs poles. Our Cassini mission studies Saturnβs magnetic field and auroras, as well as its moon Enceladus.
Uranusβ magnetosphere wasnβt discovered until 1986 when data from Voyager 2βs flyby revealed weak, variable radio emissions. Uranusβ magnetic field and rotation axis are out of alignment by 59 degrees, unlike Earthβs, whose magnetic field and rotation axis differ by only 11 degrees. On top of that, the magnetic field axis does not go through the center of the planet, so the strength of the magnetic field varies dramatically across the surface. This misalignment also means that Uranusβ magnetotail β the part of the magnetosphere that trails away from the sun β is twisted into a long corkscrew.
Neptuneβs magnetosphere is also tilted from its rotation axis, but only by 47. Just like on Uranus, Neptuneβs magnetic field strength varies across the planet. This also means that auroras can be seen away from the planetβs poles β not just at high latitudes, like on Earth, Jupiter and Saturn.
Does Every Planet Have a Magnetosphere?
Neither Venus nor Mars have global magnetic fields, although the interaction of the solar wind with their atmospheres does produce what scientists call an βinduced magnetosphere.β Around these planets, the atmosphere deflects the solar wind particles, causing the solar windβs magnetic field to wrap around the planet in a shape similar to Earthβs magnetosphere.
What About Beyond Our Solar System?
Outside of our solar system, auroras, which indicate the presence of a magnetosphere, have been spotted on brown dwarfs β objects that are bigger than planets but smaller than stars.
Thereβs also evidence to suggest that some giant exoplanets have magnetospheres. As scientists now believe that Earthβs protective magnetosphere was essential for the development of conditions friendly to life, finding magnetospheres around exoplanets is a big step in finding habitable worlds. Β
