NASA Jupiter probe images huge moon Ganymede like never before (photos)

These images the JIRAM instrument aboard NASA's Juno spacecraft took on Dec. 26, 2019, provide the first infrared mapping of Ganymede's northern frontier. Frozen water molecules detected at both poles have no appreciable order to their arrangement and a different infrared signature than ice at the equator. (Image credit: NASA/JPL-Caltech/SwRI/ASI/INAF/JIRAM)

NASA's Juno Jupiter probe has captured unprecedented views of the largest moon in the solar system.

During a close flyby of Jupiter on Dec. 26, 2019, Juno mapped the north polar regions of the icy satellite Ganymede in infrared light, something no other spacecraft had done before.

The data, which Juno gathered using its Jovian Infrared Auroral Mapper (JIRAM) instrument, show that Ganymede's northern reaches are very different than locales closer to the equator of the moon, which is bigger than the planet Mercury. 

Related: In photos: Juno's amazing views of Jupiter 

The north pole of Ganymede can be seen in center of this annotated image taken by the JIRAM infrared imager aboard NASA's Juno spacecraft on Dec. 26, 2019. The thick line is 0 degrees longitude.

The north pole of Ganymede can be seen in center of this annotated image taken by the JIRAM infrared imager aboard NASA's Juno spacecraft on Dec. 26, 2019. The thick line is 0 degrees longitude.  (Image credit: NASA/JPL-Caltech/SwRI/ASI/INAF/JIRAM)

"The JIRAM data show the ice at and surrounding Ganymede's north pole has been modified by the precipitation of plasma," Alessandro Mura, a Juno co-investigator at the National Institute for Astrophysics in Rome, said in a statement. "It is a phenomenon that we have been able to learn about for the first time with Juno because we are able to see the north pole in its entirety."

This plasma consists of charged particles from the sun, which have been trapped by Jupiter's powerful magnetic field. Unlike any other moon, the 3,274-mile-wide (5,269 kilometers) Ganymede has a magnetic field of its own, which funnels the plasma toward its poles. 

A similar phenomenon occurs here on Earth, which explains why the auroras occur at high latitudes on our planet. But Ganymede has no atmosphere to obstruct and be lit up by these particles, so they slam hard into the ice at and around both poles.

As a result, Ganymede's polar ice has been pummeled into an amorphous state at the structural level. This battered ice has a different infrared signature than the highly ordered, crystalline ice at lower latitudes, mission team members said.

The $1.1 billion Juno probe launched in August 2011 and arrived at Jupiter in July 2016, on a mission to help scientists better understand the giant planet's composition, structure, formation and evolution.

Juno loops around Jupiter in a highly elliptical orbit, gathering a variety of data during close passes that occur every 53.5 Earth days. During the December 2019 encounter, Ganymede's north pole happened to be in Juno's view. So the mission team reoriented the probe, allowing it to study the mysterious region with JIRAM and other instruments.

Juno gathered about 300 infrared images, from a distance of roughly 62,000 miles (100,000 km). The images have a resolution of about 14 miles (23 km) per pixel, mission team members said.

"These data are another example of the great science Juno is capable of when observing the moons of Jupiter," Giuseppe Sindoni, program manager of the JIRAM instrument for the Italian Space Agency, said in the same statement.

Mike Wall is the author of "Out There" (Grand Central Publishing, 2018; illustrated by Karl Tate), a book about the search for alien life. Follow him on Twitter @michaeldwall. Follow us on Twitter @Spacedotcom or Facebook. 

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Mike Wall
Senior Space Writer

Michael Wall is a Senior Space Writer with Space.com and joined the team in 2010. He primarily covers exoplanets, spaceflight and military space, but has been known to dabble in the space art beat. His book about the search for alien life, "Out There," was published on Nov. 13, 2018. Before becoming a science writer, Michael worked as a herpetologist and wildlife biologist. He has a Ph.D. in evolutionary biology from the University of Sydney, Australia, a bachelor's degree from the University of Arizona, and a graduate certificate in science writing from the University of California, Santa Cruz. To find out what his latest project is, you can follow Michael on Twitter.

  • Lovethrust
    This is wonderful stuff! I am especially pleased as one of the scientists said before launch that wouldn’t be any opportunities to take (meaningful) images of the moons.
    I wonder if the longer than intended orbits opened up these opportunities?
    Reply
  • Mercury 3488
    Lovethrust said:
    This is wonderful stuff! I am especially pleased as one of the scientists said before launch that wouldn’t be any opportunities to take (meaningful) images of the moons.
    I wonder if the longer than intended orbits opened up these opportunities?

    Not necessarily, there are still the same number of Perijoves as there would have been with the original 14 day orbits. However the orbits are nearly four times longer so the mission duration is hugely extended (53.5 day orbits) so this offers different rather than more oppoprtunities.

    The biggest difference is that the JUNO Spacecraft can monitor Jupiter and the weather systems, as well as the magnetosphere over a vastly longer period, also monitoring Jupiter's near space environment over a vastly greater period within the solar cycle.

    I would have loved to have seen a very narrow angle camera been fitted alonside the existing JUNOCAM as JUNO's orbit around Jupiter would have enoabled very high resolution imagery of Jupiter's weather systems at most latitudes as well as helping to fully map all four of the Galilean moons as well as closer images of the inner four moons Thebe, Amalthea, Adrastea and Metis and the rings.
    Reply
  • Lovethrust
    Mercury 3488 said:
    Not necessarily, there are still the same number of Perijoves as there would have been with the original 14 day orbits. However the orbits are nearly four times longer so the mission duration is hugely extended (53.5 day orbits) so this offers different rather than more oppoprtunities.

    The biggest difference is that the JUNO Spacecraft can monitor Jupiter and the weather systems, as well as the magnetosphere over a vastly longer period, also monitoring Jupiter's near space environment over a vastly greater period within the solar cycle.

    I would have loved to have seen a very narrow angle camera been fitted alonside the existing JUNOCAM as JUNO's orbit around Jupiter would have enoabled very high resolution imagery of Jupiter's weather systems at most latitudes as well as helping to fully map all four of the Galilean moons as well as closer images of the inner four moons Thebe, Amalthea, Adrastea and Metis and the rings.
    I agree, what we really need is a long term orbiter dedicated to the study of Jupiter’s atmosphere. The fact that it’s now feasible to use solar power would enable to carry more fuel to stay on station.
    Reply