Add to ORKGThe longitudinal asymmetry of the Io plasma torus, as predicted by the magnetic-anomaly model and observed by Earth-based optical astronomy, provides a driving mechanism for a corotating convection system in Jupiter's magnetosphere. Here we deduce some qualitative properties of this convection system from the general equations that govern a steady state corotating convection system (although we expect that time-dependent effects may also have to be included for a complete description of Jovian convection). The corotating convection system appears capable of providing both the dominant radial transport mechanism (with a time scale possibly as short as a few rotation periods) and the dominant mechanism for extracting energy from Jupiter&...
Abstract. I argue convection-driven magnetic dynamos are in magnetostrophic balance with rather stro...
The magnetosphere of Neptune changes its magnetic configuration continuously as the planet rotates, ...
The multifluid Lyon‐Fedder‐Mobarry (MFLFM) global magnetosphere model is used to study the interacti...
The hydrogen bulge is a feature in Jupiter's upper atmosphere that co-rotates with the planetary mag...
The engine that drives the jovian magnetosphere is the mass added to the Io ion torus, accelerated t...
Abstract Discs of plasma around giant planets are natural laboratories that contain within mechanism...
Jupiter's dominant large-scale weather patterns (dimensions ~10,000 km) are zonal jets and long-live...
Examples of convection in rotating layers are presented to illustrate how convection can drive globa...
AbstractThe coupling of Jupiter's magnetosphere and ionosphere plays a vital role in creating its au...
We review in situ observations made in Jupiter and Saturn’s magnetosphere that illustrate the possib...
The coupling of Jupiter's magnetosphere and ionosphere plays a vital role in creating its auroral em...
Io continually adds mass to the Io torus and this density builds up until centrifugal force is suffi...
The gross structures of the magnetospheres of the outer planets are decided by processes quite diffe...
Jupiter’s weather layer exhibits long-term and quasi-periodic cycles of meteorological activity that...
Magnetometer and plasma science data from the Voyager 1 and Voyager 2 encounters of Jupiter are comb...
Abstract. I argue convection-driven magnetic dynamos are in magnetostrophic balance with rather stro...
The magnetosphere of Neptune changes its magnetic configuration continuously as the planet rotates, ...
The multifluid Lyon‐Fedder‐Mobarry (MFLFM) global magnetosphere model is used to study the interacti...
The hydrogen bulge is a feature in Jupiter's upper atmosphere that co-rotates with the planetary mag...
The engine that drives the jovian magnetosphere is the mass added to the Io ion torus, accelerated t...
Abstract Discs of plasma around giant planets are natural laboratories that contain within mechanism...
Jupiter's dominant large-scale weather patterns (dimensions ~10,000 km) are zonal jets and long-live...
Examples of convection in rotating layers are presented to illustrate how convection can drive globa...
AbstractThe coupling of Jupiter's magnetosphere and ionosphere plays a vital role in creating its au...
We review in situ observations made in Jupiter and Saturn’s magnetosphere that illustrate the possib...
The coupling of Jupiter's magnetosphere and ionosphere plays a vital role in creating its auroral em...
Io continually adds mass to the Io torus and this density builds up until centrifugal force is suffi...
The gross structures of the magnetospheres of the outer planets are decided by processes quite diffe...
Jupiter’s weather layer exhibits long-term and quasi-periodic cycles of meteorological activity that...
Magnetometer and plasma science data from the Voyager 1 and Voyager 2 encounters of Jupiter are comb...
Abstract. I argue convection-driven magnetic dynamos are in magnetostrophic balance with rather stro...
The magnetosphere of Neptune changes its magnetic configuration continuously as the planet rotates, ...
The multifluid Lyon‐Fedder‐Mobarry (MFLFM) global magnetosphere model is used to study the interacti...