February 16, 2005: The dancing light of the auroras on Saturn behaves in ways different from how scientists have thought possible for the last 25 years. New research by a team of astronomers led by John Clarke of Boston University has overturned theories about how Saturn's magnetic field behaves and how its auroras are generated.See the rest:
Auroras are initiated when charged particles in space collide with a planet's magnetic field and stream into the upper atmosphere. Collisions with gases in the planet's atmosphere produce flashes of glowing energy in the form of radio waves and light (visible, ultraviolet, and infrared). Seen from space, an aurora appears as a ring of light circling a planet's polar region, where magnetic poles typically reside.
A magnetic field is a region of space in which magnetic forces may be detected or may affect the motion of an electrically charged particle. Earth has a magnetic field. One way to see the effects of the Earth's magnetic field is by using a compass. The needle on a compass always points north, because the influence of the Earth's magnetic field forces the metal needle to point toward the Earth's magnetic pole. The same effect occurs with charged particles (ions and electrons) around Earth. They are forced to move toward the magnetic north or south pole.
The Earth and all of the giant planets (Jupiter, Saturn, Uranus, and Neptune) have magnetic fields. Venus does not, and Mars has only very weak, local magnetic effects.
Auroral storms are a normal phenomenon. They occur whenever a magnetic field is present to direct charged particles into a planet's atmosphere where they interact with atmospheric gases and make them glow. Every planet with a magnetic field and an atmosphere has an aurora.