Litcius/Paper detail

Magnetospheres of Terrestrial Exoplanets and Exomoons: Implications for Habitability and Detection

James Green, Scott Boardsen, Chuanfei Dong

2021The Astrophysical Journal Letters19 citationsDOIOpen Access PDF

Abstract

Abstract Characterizing habitable exoplanets and/or their moons is of paramount importance. Here we show the results of our magnetic field topological modeling, which demonstrate that terrestrial exoplanet–exomoon coupled magnetospheres work together to protect the early atmospheres of both the exoplanet and the exomoon. When exomoon magnetospheres are within the exoplanet's magnetospheric cavity, the exomoon magnetosphere acts like a protective magnetic bubble providing an additional magnetopause confronting the stellar winds when the moon is on the dayside. In addition, magnetic reconnection would create a critical pathway for the atmosphere exchange between the early exoplanet and exomoon. When the exomoon's magnetosphere is outside of the exoplanet's magnetosphere it then becomes the first line of defense against strong stellar winds, reducing the exoplanet's atmospheric loss to space. A brief discussion is given on how this type of exomoon would modify radio emissions from magnetized exoplanets.

Topics & Concepts

ExoplanetAstrobiologyMagnetosphereHabitabilityPhysicsAtmosphere (unit)MagnetopausePlanetary habitabilityAstronomyPlanetAtmospheric escapeInterplanetary mediumTerrestrial planetExospherePlanetary scienceGas giantMagnetosphere of JupiterMagnetic reconnectionSolar SystemCircumstellar habitable zoneTidal lockingStellar atmosphereIonosphereMagnetosphere of SaturnMagnetic fieldGeophysicsStellar, planetary, and galactic studiesGeomagnetism and Paleomagnetism StudiesAstro and Planetary Science