The Origin and Fate of O 2 $\mbox{O}_{2}$ in Europa’s Ice: An Atmospheric Perspective

Johnson, R. E.; Oza, A.; Leblanc, François; Schmidt, Carl; Nordheim, Tom; Cassidy, Timothy A.

doi:10.1007/s11214-019-0582-1

Cited by 11 publications

(7 citation statements)

References 105 publications

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“…For Europa, the spatial distribution of emissions exhibits some systematic trends, but is still not fully understood. A dusk-dawn asymmetry is observed in both the UV and optical auroral data ( Roth et al 2016;de Kleer & Brown 2019), which is consistent with simulations ( Oza et al 2019) and suggests a thermal role in the production of the O 2 atmosphere ( Oza et al 2018;Johnson et al 2019). For Ganymede, the aurora appears to behave analogously to Earth's auroral ovals, whereby electrons are accelerated into the near-surface region along field lines at the open-closed field line boundary (Feldman et al 2000;Eviatar et al 2001;McGrath et al 2013).…”

Section: Introductionsupporting

confidence: 77%

The Optical Aurorae of Europa, Ganymede, and Callisto

et al. 2023

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The tenuous atmospheres of the Galilean satellites are sourced from their surfaces and produced by a combination of plasma-surface interactions and thermal processes. Even though they are thin, these atmospheres can be studied via their auroral emissions, and most work to date has focused on their aurorae at UV wavelengths. Here we present the first detections of the optical aurorae of Ganymede and Callisto, as well as detections of new optical auroral lines at Europa, based on observations of the targets over 10 Jupiter eclipses from 1998 to 2021 with Keck/HIRES. We present measurements of O i emission at 6300/6364, 5577, 7774, and 8446 Å and place upper limits on hydrogen at 6563 Å. These constitute the first detections of emissions at 7774 and 8446 Å at a planetary body other than Earth. The simultaneous measurement of multiple emission lines provides robust constraints on atmospheric composition. We find that the eclipse atmospheres of Europa and Ganymede are composed predominantly of O2, with average column densities of (4.1 ± 0.1) × 1014 cm−2 and (4.7 ± 0.1) × 1014 cm−2, respectively. We find weak evidence for H2O in Europa's bulk atmosphere at an H2O/O2 ratio of ∼0.25, and place only an upper limit on H2O in Ganymede's bulk atmosphere, corresponding to H2O/O2 < 0.6. The column density of O2 derived for Callisto is (4.0 ± 0.9) × 1015 cm−2 for an assumed electron density of 0.15 cm−3, but electron properties at Callisto's orbit are very poorly constrained.

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Section: Introductionsupporting

confidence: 77%

The Optical Aurorae of Europa, Ganymede, and Callisto

et al. 2023

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“…Instead, they will permeate or become trapped in the porous, radiation-altered regolith and, assuming reactions therein are negligible, eventually thermally desorb back into the atmosphere, where their accumulation is limited by gas-phase ionizing and dissociative processes. Thus, over time, a small ab initio source flux (Figure 5) can eventually lead to a steady-state, global, and even collisional atmosphere, where molecules are continuously returning to and thermally desorbing from the regolith (e.g., Carberry Mogan et al, 2020Mogan et al, , 2021Mogan et al, , 2022Johnson et al, 2019).…”

Section: Resultsmentioning

confidence: 99%

“…Having examined a number of additional sources (Section 5.1), we suggest that the upward flux of O 2 from the regolith principally supplies the inferred atmospheric column. O 2 can accumulate in Callisto's porous regolith as a result of being weakly bound to defect sites on grain surfaces, as suggested to account for Europa's dusk/dawn asymmetry (Johnson et al., 2019); being stably trapped in bubbles in grains (e.g., Johnson & Jesser, 1997), consistent with observations of O 2 on Callisto's surface (Spencer & Calvin, 2002); and/or being recycled therein via reactions (e.g., Shematovich, 2006; Shematovich & Johnson, 2001; Shematovich et al., 2005). Therefore, a better understanding of the production and fate of the O 2 in the regolith is required in order to place better constraints on the mechanisms for generating Callisto's O 2 atmosphere.…”

Section: Discussionmentioning

confidence: 99%

“…Johnson and Jesser (1997) described how O 2 can form and subsequently become trapped in porous regolith and/or radiation‐damaged ice at Ganymede. Formation and trapping of O 2 has recently been explored at Europa (Johnson et al., 2019). Hence, it is expected that the phenomenon could also occur at Callisto as well.…”

Section: Discussionmentioning

confidence: 99%

“…Upon release from the surface, since O 2 is too heavy and slow to escape the atmosphere and reactions therein are infrequent, it will eventually return to the surface. However, O 2 is too volatile to freeze out at Callisto's surface temperatures, so it will permeate the porous regolith (e.g., Johnson et al., 2019). Since O 2 is a relatively inert molecule, reactions in the regolith are infrequent, so that it will eventually thermally desorb back into the atmosphere.…”

Section: Introductionmentioning

confidence: 99%

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Callisto's Atmosphere: The Oxygen Enigma

Carberry Mogan,

Liuzzo,

Poppe

et al. 2023

JGR Planets

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Observations of Callisto's atmosphere have indicated an O2 component should exist, but the evolution from its initial source to its inferred steady‐state abundance is not well understood. Herein we constrain the production of O2 via radiolysis within Callisto's exposed ice patches and determine the corresponding O2 column density. To do so, for the first time we simulate the thermal and energetic components of the Jovian magnetospheric plasma irradiating Callisto's atmosphere and estimate energy deposited therein by the impinging charged particles along their trajectories to the surface. We then calculate O2 source fluxes corresponding to the energy of the impacting plasma fluxes, which is coupled with estimated atmospheric lifetimes to determine the steady‐state abundance of O2. Our results suggest that production of O2 via radiolysis within the exposed ice on Callisto's surface does not produce a sufficiently dense atmosphere relative to the column densities inferred from observations by about 2–3 orders of magnitude. To resolve this discrepancy between estimated and observed abundances, we provide the first estimates for other potential sources of atmospheric O2. We also make similar estimates for the production of H2 in Callisto's atmosphere relative to constraints provided in the literature, and the conclusion is the same: a sufficiently dense atmosphere is not produced. Thus, we have shown that a better understanding of the production and fate of radiolytic products in Callisto's regolith is required in order to place firmer constraints on the generation mechanisms of its atmosphere in preparation for future observations.

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Moons and Jupiter Imaging Spectrometer (MAJIS) on Jupiter Icy Moons Explorer (JUICE)

Poulet,

Piccioni,

Langevin

et al. 2024

Space Sci Rev

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The MAJIS (Moons And Jupiter Imaging Spectrometer) instrument on board the ESA JUICE (JUpiter ICy moon Explorer) mission is an imaging spectrometer operating in the visible and near-infrared spectral range from 0.50 to 5.55 μm in two spectral channels with a boundary at 2.3 μm and spectral samplings for the VISNIR and IR channels better than 4 nm/band and 7 nm/band, respectively. The IFOV is 150 μrad over a total of 400 pixels. As already amply demonstrated by the past and present operative planetary space missions, an imaging spectrometer of this type can span a wide range of scientific objectives, from the surface through the atmosphere and exosphere. MAJIS is then perfectly suitable for a comprehensive study of the icy satellites, with particular emphasis on Ganymede, the Jupiter atmosphere, including its aurorae and the spectral characterization of the whole Jupiter system, including the ring system, small inner moons, and targets of opportunity whenever feasible. The accurate measurement of radiance from the different targets, in some case particularly faint due to strong absorption features, requires a very sensitive cryogenic instrument operating in a severe radiation environment. In this respect MAJIS is the state-of-the-art imaging spectrometer devoted to these objectives in the outer Solar System and its passive cooling system without cryocoolers makes it potentially robust for a long-life mission as JUICE is. In this paper we report the scientific objectives, discuss the design of the instrument including its complex on-board pipeline, highlight the achieved performance, and address the observation plan with the relevant instrument modes.

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The Origin and Fate of O 2 $\mbox{O}_{2}$ in Europa’s Ice: An Atmospheric Perspective

Cited by 11 publications

References 105 publications

The Optical Aurorae of Europa, Ganymede, and Callisto

The Optical Aurorae of Europa, Ganymede, and Callisto

Callisto's Atmosphere: The Oxygen Enigma

Moons and Jupiter Imaging Spectrometer (MAJIS) on Jupiter Icy Moons Explorer (JUICE)

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