Scientists shocked by reversed electric field around Earth

Because electric forces move from positive to negative charges, scientists once assumed the magnetosphere was positively charged on the morning side and negatively charged on the evening side. However, recent satellite measurements have overturned that long-standing idea, revealing that the actual charge distribution is the reverse of what was expected.

This surprising finding led researchers from Kyoto University, Nagoya University, and Kyushu University to revisit how the magnetosphere's electric characteristics are formed and sustained.

To test their hypotheses, the team used large-scale magnetohydrodynamic (MHD) simulations to recreate conditions in near-Earth space. Their model included a steady stream of high-speed solar wind, the constant flow of charged particles emitted by the sun. The results supported the recent satellite observations, showing that the morning side of the magnetosphere carries a negative charge while the opposite side is positive -- but this pattern does not apply everywhere.

In the polar regions, the charge polarity matches the traditional theory. Near the equator, though, the pattern flips across a wide area, creating a striking difference between the two zones.

Plasma Motion Explains the Mystery

"In conventional theory, the charge polarity in the equatorial plane and above the polar regions should be the same. Why, then, do we see opposite polarities between these regions? This can actually be explained by the motion of plasma," explains corresponding author Yusuke Ebihara of Kyoto University.

When magnetic energy from the sun enters Earth's magnetic field, it moves clockwise on the dusk side of the planet and channels toward the poles. Meanwhile, Earth's magnetic field lines run from the Southern Hemisphere to the Northern Hemisphere -- upward near the equator and downward near the poles. This opposing orientation between the magnetic field and plasma flow leads to the reversal in charge distribution between the regions.

"The electric force and charge distribution are both results, not causes, of plasma motion," says Ebihara. This insight reframes how scientists interpret electrical activity in Earth's near-space environment.

Broader Implications for Planetary Science

Plasma convection -- the large-scale flow of charged particles within the magnetosphere -- drives many dynamic space phenomena. Recent studies also suggest that this movement influences Earth's radiation belts, which are regions filled with fast-moving, high-energy particles.

By clarifying how plasma motion shapes electric fields, this research deepens understanding of large-scale space plasma behavior. It also sheds light on similar processes occurring around other magnetized worlds, including Jupiter and Saturn, expanding our grasp of how planetary environments evolve across the solar system.