The magnetospheres of giant planets are governed by the interplay of these planets’ fast rotation, the solar wind and inner plasma sources. In the Saturn and Jupiter magnetospheres, plasma is mainly produced by the ionization of neutral gas tori at the radial location of active moons: Io at Jupiter and Enceladus at Saturn. The mechanisms by which these moon-associated plasma sources are re- distributed throughout these magnetospheres involve both plasma motions and magnetic flux tube exchanges. These motions are coupled to the rotation of the planets through electric current systems originating in the equatorial plasma disk and closing into their upper atmosphere and ionosphere. Models of the net effects of these different mechanisms on the...
Jupiter is the archetype of a rotation-driven magnetosphere dominated by an internal source of plasm...
International audienceThe dynamics of the Jovian magnetosphere are controlled by the interplay of th...
Jupiter's plasma environment is one of the most interesting plasma laboratories in our solar System....
The magnetospheres of giant planets are governed by the interplay of these planets’ fast rotation, t...
The configuration and dynamics of planetary magnetospheres are controlled by the interplay of their ...
The gross structures of the magnetospheres of the outer planets are decided by processes quite diffe...
The magnetospheres of the giant outer planets Jupiter and Saturn are characterized by strong intrins...
At orbital distances of 5 AU and beyond, the low solar wind dynamic pressure and weak interplanetary...
Some aspects of M-I coupling are universal from one planet to another, for example, the crucial role...
The giant planets in our solar system such as Saturn and Jupiter represent fascinating worlds which ...
An important aspect of solar system plasma physics is the linkage and coupling of denser, colder ion...
International audienceWe propose a simple illustrative axisymmetric model of the plasma flow and cur...
We present calculations of magnetic potential functions associated with the perturbation of Saturn's...
We have developed global magnetohydrodynamic (MHD) models of the magnetospheres of Jupiter and Satur...
Jupiter is the archetype of a rotation-driven magnetosphere dominated by an internal source of plasm...
International audienceThe dynamics of the Jovian magnetosphere are controlled by the interplay of th...
Jupiter's plasma environment is one of the most interesting plasma laboratories in our solar System....
The magnetospheres of giant planets are governed by the interplay of these planets’ fast rotation, t...
The configuration and dynamics of planetary magnetospheres are controlled by the interplay of their ...
The gross structures of the magnetospheres of the outer planets are decided by processes quite diffe...
The magnetospheres of the giant outer planets Jupiter and Saturn are characterized by strong intrins...
At orbital distances of 5 AU and beyond, the low solar wind dynamic pressure and weak interplanetary...
Some aspects of M-I coupling are universal from one planet to another, for example, the crucial role...
The giant planets in our solar system such as Saturn and Jupiter represent fascinating worlds which ...
An important aspect of solar system plasma physics is the linkage and coupling of denser, colder ion...
International audienceWe propose a simple illustrative axisymmetric model of the plasma flow and cur...
We present calculations of magnetic potential functions associated with the perturbation of Saturn's...
We have developed global magnetohydrodynamic (MHD) models of the magnetospheres of Jupiter and Satur...
Jupiter is the archetype of a rotation-driven magnetosphere dominated by an internal source of plasm...
International audienceThe dynamics of the Jovian magnetosphere are controlled by the interplay of th...
Jupiter's plasma environment is one of the most interesting plasma laboratories in our solar System....