11:30 〜 11:45
[PPS01-09] Evidence for H2 in Callisto's atmosphere
キーワード:Callisto, JUICE, Atmosphere, Hubble Space Telescope, Galilean Satellites, Galileo
We explore the parameter space for the composition of Callisto's atmosphere with contributions to its H corona from sublimated H2O and radiolytically produced H2 using the Direct Simulaton Monte Carlo (DSMC) method [1]. The 2D spatial morphology of the observed H corona produced by photon and magnetospheric electron induced dissociation at eastern elongation [2] is described by tracking the motion of and collisions between the hot H atoms and thermal molecules in Callisto's atmosphere. Sublimated H2O produced from the surface ice, whether assumed to be intimately mixed with or distinctly segregated from the dark, non-ice or ice-poor regolith, cannot explain the structure of the H corona. The observation instead suggests the presence of a roughly global source, which we suggest is H2 as we originally proposed in an earlier study [3]. Such a source is also roughly consistent with the Galileo plasma-wave observations [4, 5]. This provides the first direct evidence of H2 in Callisto's atmosphere. Comparison with the morphology of the observed H corona allows us to estimate the surface source rate of H2 (~2x1028 s-1, ~67 kg/s) and to place a rough upper limit on the peaks in H2O density (<~108 cm-3) and sublimation flux (<~1012 cm-2 s-1). The latter is 1-2 orders of magnitude less than that assumed in previous models [3, 6-8]. These constraints, along with the concomitant H2 escape rates are used to obtain estimates for a neutral H2 torus co-rotating with Callisto. With a closest approach of 200 km the Neutral gas and Ion Mass spectrometer on board JUICE should be able to measure the neutral gas densities for H2O, H2, and H presented here on the day-side, with detections of H2O becoming more difficult with increasing distance from the subsolar point. In addition, we show that collisions in the atmosphere can have a significant affect on the density distribution of nascent light species, such as that of the H, which in some of the instances considered here inflated by more than an order of magnitude as a result of such interactions, and thus need to be considered when predicting JUICE atmospheric measurements. Based on these results, the role of H2 versus H2O as a source of the H corona needs re-examining at Europa [9] and Ganymede [10-11].
References:
[1] Bird (1994): Molecular gas dynamics and the direct simulation of gas flows.
[2] Roth, L. et al. (2017): Detection of a hydrogen corona at Callisto. Journal of Geophysical Research: Planets.
[3] Carberry Mogan, S. R. et al. (2021): A tenuous, collisional atmosphere on Callisto. Icarus.
[4] Gurnett, D. A. et al. (1997): Absence of a magnetic-field signature in plasma-wave observations at Callisto. Nature.
[5] Gurnett, D. A. et al. (2000): Plasma densities in the vicinity of Callisto from Galileo plasma wave observations. Geophysical Research Letters.
[6] Liang, M.C. et al. (2005): Atmosphere of Callisto. Journal of Geophysical Research: Planets.
[7] Hartkorn, O. et al. (2017): Structure and density of Callisto’s atmosphere from a fluid-kinetic model of its ionosphere: Comparison with Hubble Space Telescope and Galileo observations. Icarus.
[8] Vorburger, A. et al. (2015): Monte-Carlo simulation of Callisto’s exosphere. Icarus.
[9] Roth, L. et al. (2017): Detection of a hydrogen corona in HST Lyman-alpha images of Europa in transit of Jupiter. The Astronomical Journal.
[10] Barth, C. A. et al. (1997): Galileo ultraviolet spectrometer observations of atomic hydrogen in the atmosphere of Ganymede. Geophysical Research Letters.
[11] Feldman, P. D. et al. (2000): HST/STIS ultraviolet imaging of polar aurora on Ganymede. The Astrophysical Journal.
References:
[1] Bird (1994): Molecular gas dynamics and the direct simulation of gas flows.
[2] Roth, L. et al. (2017): Detection of a hydrogen corona at Callisto. Journal of Geophysical Research: Planets.
[3] Carberry Mogan, S. R. et al. (2021): A tenuous, collisional atmosphere on Callisto. Icarus.
[4] Gurnett, D. A. et al. (1997): Absence of a magnetic-field signature in plasma-wave observations at Callisto. Nature.
[5] Gurnett, D. A. et al. (2000): Plasma densities in the vicinity of Callisto from Galileo plasma wave observations. Geophysical Research Letters.
[6] Liang, M.C. et al. (2005): Atmosphere of Callisto. Journal of Geophysical Research: Planets.
[7] Hartkorn, O. et al. (2017): Structure and density of Callisto’s atmosphere from a fluid-kinetic model of its ionosphere: Comparison with Hubble Space Telescope and Galileo observations. Icarus.
[8] Vorburger, A. et al. (2015): Monte-Carlo simulation of Callisto’s exosphere. Icarus.
[9] Roth, L. et al. (2017): Detection of a hydrogen corona in HST Lyman-alpha images of Europa in transit of Jupiter. The Astronomical Journal.
[10] Barth, C. A. et al. (1997): Galileo ultraviolet spectrometer observations of atomic hydrogen in the atmosphere of Ganymede. Geophysical Research Letters.
[11] Feldman, P. D. et al. (2000): HST/STIS ultraviolet imaging of polar aurora on Ganymede. The Astrophysical Journal.