The observation is based on data from NASA's Juno spacecraft, which made a historic low orbit flight over Jupiter's north pole, where the team was able to use their expertise in data analysis to study ...

Astronomers have identified a new type of plasma wave in Jupiter’s aurora, thanks to data collected by NASA’s Juno spacecraft ...

Researchers' analysis showed that the plasma waves have a very low frequency, unlike anything previously seen around Earth.

Scientists using NASA's Juno spacecraft have discovered a new plasma wave in Jupiter's auroras, offering fresh insight into ...

The observation is based on data from NASA’s Juno spacecraft, which made a historic low orbit flight over Jupiter’s north ...

In a remarkable breakthrough, researchers from the University of Minnesota have uncovered a new type of plasma wave in ...

Researchers at the University of Minnesota Twin Cities have made a new discovery by observing and analyzing the first new ...

The moon’s volcanic surface erupts with particles that enter Jupiter’s orbit. The magnetic field causes these particles to move at tremendous speeds, resulting in the glow of the aurora.

As JWST was being used to capture the features of Jupiter's auroras, the team also took pictures with the Hubble Space Telescope simultaneously. They were perplexed by what they saw.

On Jupiter, the cation has been suggested as a possible dark matter detector, but in this study, it was used as a proxy for the aurorae variability. It turns out that they change faster than ...

While Jupiter's Aurora is the brightest in our solar system due to its size and gas-rich atmosphere, our neighboring red planet also exhibits breathtaking, visible-light auroras.

Jupiter’s magnetosphere is the largest and most dynamic in the Solar System, a vast region where the planet’s powerful magnetic field governs the behaviour of charged particles.