?
Acceleration of Electrons in Plasmospheres of Hot Jupiter-Type Exoplanets with a Relatively Weak Magnetic Field
Abstract—In analogy with the acceleration mechanism implemented in the Jupiter–Io system, the electron
acceleration mechanism is discussed with the example of the plasmasphere of exoplanet HD 189733b. Under
conditions when the oncoming stellar wind flow with the stellar magnetic field included in it reaches a region
of the atmosphere with a sufficient number of neutral particles, the different frequencies of collisions of stellar
electrons and ions with neutrals ensure charge separation and the emergence of an electric field of charge separation.
In this process, an important role is played by the anisotropy of the conductivity of the exoplanet’s
plasmasphere, which ultimately leads to a powerful electric field, that has a projection on the direction of the
magnetic field and causes electron acceleration. The characteristic energies and fluxes of accelerated electrons
for exoplanet HD 189733b are estimated. The possibilities of this acceleration mechanism are discussed
from the viewpoint of the occurrence of plasma instability in the atmosphere of the exoplanet and generation
of a radio emission flux necessary for recording on Earth. A conclusion is drawn about the energy sufficiency
of the proposed acceleration mechanism for observing the radio emission of this exoplanet. The possibilities
of implementing the electron acceleration mechanism described above for the other two most studied hot
Jupiter-type exoplanets—WASP 12 b and HD 209458 b—are also discussed.