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Plutos Ultraviolet Spectrum, Surface Reflectance, and Airglow Emissions

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 Added by Andrew Steffl
 Publication date 2020
  fields Physics
and research's language is English




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During the New Horizons spacecrafts encounter with Pluto, the Alice ultraviolet spectrograph conducted a series of observations that detected emissions from both the interplanetary medium (IPM) and Pluto. In the direction of Pluto, the IPM was found to be 133.4$pm$0.6R at Lyman $alpha$, 0.24$pm$0.02R at Lyman $beta$, and <0.10R at He I 584{AA}. We analyzed 3,900s of data obtained shortly before closest approach to Pluto and detect airglow emissions from H I, N I, N II, N$_2$, and CO above the disk of Pluto. We find Plutos brightness at Lyman $alpha$ to be $29.3pm1.9$R, in good agreement with pre-encounter estimates. The detection of the N II multiplet at 1085{AA} marks the first direct detection of ions in Plutos atmosphere. We do not detect any emissions from noble gasses and place a 3$sigma$ upper limit of 0.14 R on the brightness of the Ar I 1048{AA} line. We compare pre-encounter model predictions and predictions from our own airglow model, based on atmospheric profiles derived from the solar occultation observed by New Horizons, to the observed brightness of Plutos airglow. Although completely opaque at Lyman $alpha$, Plutos atmosphere is optically thin at wavelengths longer than 1425{AA}. Consequently, a significant amount of solar FUV light reaches the surface, where it can participate in space weathering processes. From the brightness of sunlight reflected from Pluto, we find the surface has a reflectance factor (I/F) of 17% between 1400-1850{AA}. We also report the first detection of an C$_3$ hydrocarbon molecule, methylacetylene, in absorption, at a column density of ~5$times10^{15}$ cm$^{-2}$, corresponding to a column-integrated mixing ratio of $1.6times10^{-6}$.



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The New Horizons spacecraft provided near global observations of Pluto that far exceed the resolution of Earth-based data sets. Most Pluto New Horizons analysis hitherto has focused on the encounter hemisphere of Pluto (i.e., the antiCharon hemisphere containing Sputnik Planitia). In this work, we summarize and interpret data on the far side (i.e., the non-encounter hemisphere), providing the first integrated New Horizons overview of the far side terrains. We find strong evidence for widespread bladed deposits, evidence for an impact crater about as large as any on the near side hemisphere, evidence for complex lineations approximately antipodal to Sputnik Planitia that may be causally related, and evidence that the far side maculae are smaller and more structured than the encounter hemisphere maculae.
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