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Particle-induced emission of X-rays from the Europa (100-10keV)


Affiliations
1 Department of Atmospheric Sciences, Cochin University of Science and Technology, Kochi, Kerala 682 016, India
2 Department of Atmospheric Sciences, Cochin University of Science and Technology, Kochi, Kerala 682 016,, India
 

We considered the interaction of H+, O+ and S+ ions of spectral energy range 100-10keV with the predominant H2Oice composition of the surface of the Jovian Europa, and developed a model to quantify the ion-induced emission of X-rays from the satellite during its three encounters with Galileo mission flyby (E12, E19, E26). To achieve this, we computed the stopping power of H2O ice using SRIM code, and X-ray ionization cross sections of interaction for the ions with H2Oice using ISICS14 code. We found that the integrated fluxes of H+, O+ and S+ ions are seen as lower above the current sheet (E19) and enhanced through the centre of the current sheet (E12) and below the current sheet (E26). The proton-induced energy flux received at the telescope of the Chandra X-ray Observatory (ergs-cm-2-s-1) during E12encounter is 9.49E-11, during E19encounter is 4.79E-11, and during E26encounter is 9.39E-11. The energy flux generated by O+ and S+ ions is found as trivial in comparison to the proton-induced energy flux (100-10 keV).
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  • Particle-induced emission of X-rays from the Europa (100-10keV)

Abstract Views: 194  |  PDF Views: 97

Authors

Smart Kundaserry Bright
Department of Atmospheric Sciences, Cochin University of Science and Technology, Kochi, Kerala 682 016, India
C A Babu
Department of Atmospheric Sciences, Cochin University of Science and Technology, Kochi, Kerala 682 016,, India

Abstract


We considered the interaction of H+, O+ and S+ ions of spectral energy range 100-10keV with the predominant H2Oice composition of the surface of the Jovian Europa, and developed a model to quantify the ion-induced emission of X-rays from the satellite during its three encounters with Galileo mission flyby (E12, E19, E26). To achieve this, we computed the stopping power of H2O ice using SRIM code, and X-ray ionization cross sections of interaction for the ions with H2Oice using ISICS14 code. We found that the integrated fluxes of H+, O+ and S+ ions are seen as lower above the current sheet (E19) and enhanced through the centre of the current sheet (E12) and below the current sheet (E26). The proton-induced energy flux received at the telescope of the Chandra X-ray Observatory (ergs-cm-2-s-1) during E12encounter is 9.49E-11, during E19encounter is 4.79E-11, and during E26encounter is 9.39E-11. The energy flux generated by O+ and S+ ions is found as trivial in comparison to the proton-induced energy flux (100-10 keV).