The Phobos neutral and ionized torus

Poppe, A. R.; Curry, S.; Fatemi, Shahab

doi:10.1002/2015je004948

Cited by 9 publications

(9 citation statements)

References 85 publications

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“…These enhancements and their durations can clearly be sufficient to significantly increase densities in the putative neutral torus of Phobos. Poppe et al () presented a numerical model of the Phobos neutral torus assuming a sputtered flux consistent with the long‐term value obtained in this study. A modeling effort could be conducted in the future to balance the increase of surface sputtered rate with the likely shortened neutral lifetime against ionization, to determine if and to what extent densities in the neutral torus of Phobos increased in March 2015.…”

Section: Summary and Discussionsupporting

confidence: 86%

“…In any case, both the increase of surface sputtered rate and ionization rate will result in an increase of the flux of ions created from the putative Phobos neutral torus. Poppe et al (2016) detail that these ions can be used to unambiguously detect the Phobos neutral torus, and section 5 of this study points out that periods of solar wind activity are conducive to this discovery.…”

Section: Journal Of Geophysical Research: Planetsmentioning

confidence: 92%

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Phobos Surface Sputtering as Inferred From MAVEN Ion Observations

et al. 2019

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Phobos is bombarded by both protons and alpha particles from the solar wind and by Martian atomic and molecular oxygen ions. A numerical model of the distribution of planetary ions has previously proposed that these ions may dominate solar wind ions in sputtering the surface of Phobos when the moon is located downstream of Mars. This conclusion suggests a unique link between planetary atmospheric escape at Mars and the surface processing of its moon yet, remains to be confirmed with in situ ion measurements. In this article, a 4‐year‐long average of the ion environment that Phobos is exposed to is constructed from in situ ion observations conducted by the Mars Atmosphere and Volatile Evolution (MAVEN) mission. In turn, the flux of material sputtered from the surface of Phobos by this environment is computed. We confirm that planetary atomic oxygen ions dominate over solar wind ions in sputtering the surface of Phobos downstream of Mars during 20% of the moon's orbit. We also reveal that molecular oxygen ions sputter the surface of Phobos as much as or more than atomic oxygen ions in the Martian magnetotail. In addition to the long‐term average picture, the time variation of Phobos surface sputtered fluxes is investigated during the series of solar wind events that hit the Martian system in March 2015. We find that the flux of material liberated from Phobos' surface increased by a factor of 50 during this period.

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Section: Summary and Discussionsupporting

confidence: 86%

Section: Journal Of Geophysical Research: Planetsmentioning

confidence: 92%

Phobos Surface Sputtering as Inferred From MAVEN Ion Observations

et al. 2019

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“…Table 1 also shows a comparison to the Phobos surface composition used in the modeling by Poppe and Curry (2014) and Poppe et al. (2016), originally proposed by Vernazza et al. (2010) and Cipriani et al.…”

Section: Methodsmentioning

confidence: 99%

“…The values are averaged over the whole film, but very uniform film compositions were measured with ToF-ERDA. Table 1 also shows a comparison to the Phobos surface composition used in the modeling by Poppe and Curry (2014) and Poppe et al (2016), originally proposed by Vernazza et al (2010) and Cipriani et al (2011). It was derived from asteroid compositions, whose infrared spectra were found to agree well with Phobos.…”

Section: Quartz Crystal Microbalance Samplesmentioning

confidence: 95%

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Experimental Insights Into Space Weathering of Phobos: Laboratory Investigation of Sputtering by Atomic and Molecular Planetary Ions

et al. 2020

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Key Points: • Experiments with Phobos analogs were carried out to evaluate the sputtering by O + , C + , O2 + and CO2 + ions from the Martian atmosphere. • The sputter yield from O ions is lower than previously assumed and no yield increases due to molecular effects were observed. • Previous predictions that planetary O ions will dominate sputtering in the Martian tail region are supported by the measurements presented.

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