Abstract
In the frame of the JUICE mission, preliminary studies of the Jupiter’s icy moons, such as Ganymede and Europa, are mandatory. The present paper aims at characterizing the impact of the solar UV flux and its variability on their atmospheres. The solar UV radiation is responsible for the photoionization, photodissociation, and photoexcitation processes within planetary atmospheres. A 1-D photoabsorption model has been developed for different observational geometries, on the basis of a neutral atmospheric model. Considering various production and loss mechanisms but also the transport of oxygen atoms, we estimate the red and green line emissions from photo impact-induced excitation only. These dayglow emissions can represent few percent of the global airglow emission, mainly dominated by electron-induced excitation in auroral regions. For limb viewing conditions, red line emission is bright enough to be detected from actual spectrometers, from 338 R to 408 R according to the solar activity. This is also the case for the green line with 8 R at limb viewing. Considering a different neutral atmosphere model, with an O2 column density 50% more important, leads to a 14% increase in the red line emissions for limb viewing close to the surface. This difference could be important enough to infer which neutral model is the most likely. However, uncertainties on the solar UV flux might also prevent to constrain the O2 column density when using ground-based observations in the visible only. The impact of solar flares on the red line emissions for Europa has also been investigated within a planetary space weather context.
Highlights
Introduction and motivationsPlanetary space weather is currently an area of high scientific interest (Lilensten et al 2014), especially in the frame of the exploration of planetary environments such as the Jovian icy moons
In a more general space weather frame, the second motivation is following Barthelemy & Cessateur (2014) studies on the solar UV flux accuracy to demonstrate on a case study, i.e. Europa and Ganymede, how the knowledge of the solar UV flux is of primary importance regarding the visible red and green dayglow emission estimations especially in the case of solar eruptive events
For a high solar activity level, red line emissions are quite variable, from 408.5 R to 433.1 R, in the case of the first neutral atmospheric model. Such a discrepancy is obviously coming from differences within the solar UV flux: the solar Lyman a line as well as the continuum between 130 and 180 nm are more intense within the Atlas spectrum compared to SOLar Radiation and Climate Experiment (SORCE)/SOLSTICE and TIMED/Solar Extreme Ultraviolet Experiment (SEE) observations
Summary
Planetary space weather is currently an area of high scientific interest (Lilensten et al 2014), especially in the frame of the exploration of planetary environments such as the Jovian icy moons. In a more general space weather frame, the second motivation is following Barthelemy & Cessateur (2014) studies on the solar UV flux accuracy to demonstrate on a case study, i.e. Europa and Ganymede, how the knowledge of the solar UV flux is of primary importance regarding the visible red and green dayglow emission estimations especially in the case of solar eruptive events Since those estimations are directly linked to both the neutral atmospheric model of the planetary object and the solar UV flux, a flawed knowledge of the last one leads to an important uncertainty in the deduced atmospheric compositions.
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