Litcius/Paper detail

Observational evidence of ring current in the magnetosphere of Mercury

Jiutong Zhao, Qiugang Zong, Chuan Yue, W. Sun, Hui Zhang, X.-Z. Zhou, G. Le, R. Rankin, J. A. Slavin, J. M. Raines, Ying Liu, Yong Wei

2022Nature Communications21 citationsDOIOpen Access PDF

Abstract

The magnetic gradient and curvature drift of energetic ions can form a longitudinal electric current around a planet known as the ring current, that has been observed in the intrinsic magnetospheres of Earth, Jupiter, and Saturn. However, there is still a lack of observational evidence of ring current in Mercury's magnetosphere, which has a significantly weaker dipole magnetic field. Under such conditions, charged particles are thought to be efficiently lost through magnetopause shadowing and/or directly impact the planetary surface. Here, we present the observational evidence of Mercury's ring current by analysing particle measurements from MErcury Surface, Space Environment, GEochemistry, and Ranging (MESSENGER) spacecraft. The ring current is bifurcated because of the dayside off-equatorial magnetic minima. Test-particle simulation with Mercury's dynamic magnetospheric magnetic field model (KT17 model) validates this morphology. The ring current energy exceeds [Formula: see text] J during active times, indicating that magnetic storms may also occur on Mercury.

Topics & Concepts

Ring currentMagnetosphereMagnetopausePhysicsMercury's magnetic fieldDipolePlanetMercury (programming language)Magnetic fieldCurrent sheetMagnetic dipoleGeophysicsComputational physicsAstrobiologyAstrophysicsEarth's magnetic fieldL-shellMagnetohydrodynamicsQuantum mechanicsProgramming languageComputer scienceIonosphere and magnetosphere dynamicsGeomagnetism and Paleomagnetism StudiesAstro and Planetary Science