Cassini end its mission by plunging into Saturn NASA/JPL-Caltech
Cassini is dead, but its legacy lives on. Before the NASA spacecraft plunged into Saturn and burned up last September, it made 22 daring final orbits, swooping between the planet and its rings in a mission called the Grand Finale. Now, researchers are analysing the data from the that mission, and there are a few surprises.
Saturn鈥檚 magnetic field is weirdly flat
The magnetic fields of planets in our solar system are all tilted to some extent 鈥 Neptune鈥檚 is off by a whopping 47 degrees. But Saturn鈥檚 magnetic field seems to be perfectly straight, and our current theories of how these fields are generated suggests that should be impossible.
鈥淚f you don鈥檛 have a tilt, you would expect the magnetic field to start dying away, but as we got in really close with the Grand Finale orbits, we saw that it is not,鈥 says Michele Dougherty at Imperial College London.
That might mean that Saturn produces its magnetic field differently from the other planets in our solar system, maybe with many onion-like layers of flowing particles producing the field instead of a single zone.
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Saturn has a lot going on between its rings
Even the seemingly empty space between Saturn鈥檚 surface and its rings is more exciting than we thought. 鈥淭here鈥檚 this connection between the rings and the upper atmosphere of Saturn that we just didn鈥檛 think would be there,鈥 says Dougherty. 鈥淭hat was a complete surprise.鈥
That connection is in the form of streaming electric currents that flow between the rings and the upper atmosphere. It鈥檚 not yet clear what鈥檚 causing them or why they鈥檙e there, says Dougherty, but she hopes that combining the data from different Cassini instruments will help us figure it out.
The currents aren鈥檛 all – there鈥檚 also a belt of radiation coming from trapped energetic particles between the rings and the planet. It鈥檚 similar to Earth鈥檚 Van Allen belts, which can be dangerous for astronauts and spacecraft that might pass through them, says William Kurth at the University of Iowa.
It鈥檚 not clear how those particles got there, though. 鈥淪ince Saturn has this elaborate ring system, it鈥檚 difficult to get energetic particles from the outer areas across the rings,鈥 Kurth says. Figuring out how the belt formed could help us understand similar zones of radiation around other planets.
Saturn鈥檚 rings rain the equivalent of 1800 cars per minute
Between Saturn鈥檚 innermost rings and the top of its atmosphere is a deluge of tiny particles falling down from the rings into the planet, called ring rain. Cassini found that, around Saturn鈥檚 equator, this rain deposits up to 45,000 kilograms of dust, ice, and gas every second.
That鈥檚 the equivalent of about 1800 cars falling into Saturn every minute – such a downpour may mean that the rings are disappearing faster than we thought.
While the rings are made of mostly water ice, the rain is much more diverse, with ammonia, nitrogen, methane, and even more complex organic particles. This may affect the chemistry of the top layers of Saturn, says Hunter Waite at Southwest Research Institute in Texas.
This downfall was not obvious before Cassini because it鈥檚 spread over a large area. 鈥淚t鈥檚 not like rain, really – more like a really fine mist that you can鈥檛 even really see,鈥 says Waite. 鈥淭he particles are so small that I don鈥檛 think you鈥檇 feel them if you were floating between Saturn and its rings.鈥
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