Topography and geology of Uranian mid-sized icy satellites in comparison with Saturnian and Plutonian satellites

2020 ◽  
Vol 378 (2187) ◽  
pp. 20200102
Author(s):  
Paul M. Schenk ◽  
Jeffrey M. Moore
Keyword(s):  
Internal Heat ◽  
Dominant Mode ◽  
Surface Processes ◽  
Topographic Mapping ◽  
Icy Satellites ◽  
Satellite Systems ◽  
New Horizons ◽  
Uranian Satellites ◽  
Volatile Transport ◽  
Fault Network

Newly processed global imaging and topographic mapping of Uranus's five major satellites reveal differences and similarities to mid-sized satellites at Saturn and Pluto. Three modes of internal heat redistribution are recognized. The broad similarity of Miranda's three oval resurfacing zones to those mapped on Enceladus and (subtly) on Dione are likely due to antipodal diapiric upwelling. Conversely, break-up and foundering of crustal blocks accompanied by extensive (cryo)volcanism is the dominant mode on both Charon and Ariel. Titania's fault network finds parallels on Rhea, Dione, Tethys and possibly Oberon. Differences in the geologic style of resurfacing in the satellite systems (e.g. plains on Charon, Dione, Tethys and perhaps Titania versus ridges on Miranda and Ariel) may be driven by differences in ice composition. Surface processes such as volatile transport may also be indicated by bright and dark materials on Oberon, Umbriel and Charon. The more complete and higher quality observations of the Saturnian and Plutonian mid-sized icy satellites by Cassini and New Horizons reveal a wealth of features and phenomena that cannot be perceived in the more limited Voyager coverage of the Uranian satellites, harbingers of many discoveries awaiting us on a return to Uranus. This article is part of a discussion meeting issue ‘Future exploration of ice giant systems'.

scholarly journals GEOLOGICAL MAPPING OF PLUTO AND CHARON USING NEW HORIZONS DATA

2016 ◽  
Vol XLI-B4 ◽  
pp. 449-451
Author(s):  
J. M. Moore ◽  
J. R. Spencer ◽  
W. B. McKinnon ◽  
A. D. Howard ◽  
O. M. White ◽  
...  
Keyword(s):  
Solar System ◽  
Geological Mapping ◽  
The Other ◽  
Internal Heating ◽  
Systematic Mapping ◽  
Radiogenic Heat ◽  
Western Margin ◽  
New Horizons ◽  
Extensional Tectonic ◽  
Volatile Transport

Pluto and Charon exhibit strikingly different surface appearances, despite their similar densities and presumed bulk compositions. Systematic mapping has revealed that much of Pluto’s surface can be attributed to surface-atmosphere interactions and the mobilization of volatile ices by insolation. Many mapped valley systems appear to be the consequence of glaciation involving nitrogen ice. Other geological activity requires or required internal heating. The convection and advection of volatile ices in Sputnik Planum can be powered by present-day radiogenic heat loss. On the other hand, the prominent mountains at the western margin of Sputnik Planum, and the strange, multi-km-high mound features to the south, probably composed of H2O, are young geologically as inferred by light cratering and superposition relationships. Their origin, and what drove their formation so late in Solar System history, is under investigation. The dynamic remolding of landscapes by volatile transport seen on Pluto is not unambiguously evident in the mapping of Charon. Charon does, however, display a large resurfaced plain and globally engirdling extensional tectonic network attesting to its early endogenic vigor.

scholarly journals TOPOGRAPHIC MAPPING OF PLUTO AND CHARON USING NEW HORIZONS DATA

2016 ◽  
Vol XLI-B4 ◽  
pp. 487-489 ◽  
Author(s):  
P. M. Schenk ◽  
R. A. Beyer ◽  
J. M. Moore ◽  
J. R. Spencer ◽  
W. B. McKinnon ◽  
...  
Keyword(s):  
High Resolution ◽  
Viscous Flow ◽  
High Impact ◽  
Impact Craters ◽  
Topographic Maps ◽  
Topographic Mapping ◽  
New Horizons ◽  
Rolling Plains

New Horizons 2015 flyby of the Pluto system has resulted in high-resolution topographic maps of Pluto and Charon, the most distant objects so mapped. DEM’s over ~30% of each object were produced at 100-300 m vertical and 300-800 m spatial resolutions, in hemispheric maps and high-resolution linear mosaics. Both objects reveal more relief than was observed at Triton. The dominant 800-km wide informally named Sputnik Planum bright ice deposit on Pluto lies in a broad depression 3 km deep, flanked by dispersed mountains 3-5 km high. Impact craters reveal a wide variety of preservation states from pristine to eroded, and long fractures are several km deep with throw of 0-2 km. Topography of this magnitude suggests the icy shell of Pluto is relatively cold and rigid. Charon has global relief of at least 10 km, including ridges of 2-3 km and troughs of 3-5 km of relief. Impact craters are up to 6 km deep. Vulcan Planum consists of rolling plains and forms a topographic moat along its edge, suggesting viscous flow.

scholarly journals Lower atmosphere and pressure evolution on Pluto from ground-based stellar occultations, 1988–2016

2019 ◽  
Vol 625 ◽  
pp. A42 ◽  
Author(s):  
E. Meza ◽  
B. Sicardy ◽  
M. Assafin ◽  
J. L. Ortiz ◽  
T. Bertrand ◽  
...  
Keyword(s):  
Transport Model ◽  
Lower Atmosphere ◽  
Seasonal Effects ◽  
Orbital Eccentricity ◽  
Temperature Variations ◽  
New Horizons ◽  
Large Factor ◽  
Stellar Occultations ◽  
Density Values ◽  
Volatile Transport

Context. The tenuous nitrogen (N2) atmosphere on Pluto undergoes strong seasonal effects due to high obliquity and orbital eccentricity, and has recently (July 2015) been observed by the New Horizons spacecraft. Aims. The main goals of this study are (i) to construct a well calibrated record of the seasonal evolution of surface pressure on Pluto and (ii) to constrain the structure of the lower atmosphere using a central flash observed in 2015. Methods. Eleven stellar occultations by Pluto observed between 2002 and 2016 are used to retrieve atmospheric profiles (density, pressure, temperature) between altitude levels of ~5 and ~380 km (i.e. pressures from ~ 10 μbar to 10 nbar). Results. (i) Pressure has suffered a monotonic increase from 1988 to 2016, that is compared to a seasonal volatile transport model, from which tight constraints on a combination of albedo and emissivity of N2 ice are derived. (ii) A central flash observed on 2015 June 29 is consistent with New Horizons REX profiles, provided that (a) large diurnal temperature variations (not expected by current models) occur over Sputnik Planitia; and/or (b) hazes with tangential optical depth of ~0.3 are present at 4–7 km altitude levels; and/or (c) the nominal REX density values are overestimated by an implausibly large factor of ~20%; and/or (d) higher terrains block part of the flash in the Charon facing hemisphere.

Coupling of volatile transport and internal heat flow on Triton

1994 ◽  
Vol 99 (E1) ◽  
pp. 1965 ◽  
Author(s):  
Robert H. Brown ◽  
Randolph L. Kirk
Keyword(s):  
Heat Flow ◽  
Internal Heat ◽  
Volatile Transport

General circulation models of the dynamics of Pluto’s volatile transport on the eve of the New Horizons encounter

Icarus ◽  
2015 ◽  
Vol 254 ◽  
pp. 306-323 ◽  
Author(s):  
Anthony D. Toigo ◽  
Richard G. French ◽  
Peter J. Gierasch ◽  
Scott D. Guzewich ◽  
Xun Zhu ◽  
...  
Keyword(s):  
General Circulation ◽  
General Circulation Models ◽  
New Horizons ◽  
Volatile Transport

scholarly journals GEOLOGICAL MAPPING OF PLUTO AND CHARON USING NEW HORIZONS DATA

2016 ◽  
Vol XLI-B4 ◽  
pp. 449-451
Author(s):  
J. M. Moore ◽  
J. R. Spencer ◽  
W. B. McKinnon ◽  
A. D. Howard ◽  
O. M. White ◽  
...  
Keyword(s):  
Solar System ◽  
Geological Mapping ◽  
The Other ◽  
Internal Heating ◽  
Systematic Mapping ◽  
Radiogenic Heat ◽  
Western Margin ◽  
New Horizons ◽  
Extensional Tectonic ◽  
Volatile Transport

Pluto and Charon exhibit strikingly different surface appearances, despite their similar densities and presumed bulk compositions. Systematic mapping has revealed that much of Pluto’s surface can be attributed to surface-atmosphere interactions and the mobilization of volatile ices by insolation. Many mapped valley systems appear to be the consequence of glaciation involving nitrogen ice. Other geological activity requires or required internal heating. The convection and advection of volatile ices in Sputnik Planum can be powered by present-day radiogenic heat loss. On the other hand, the prominent mountains at the western margin of Sputnik Planum, and the strange, multi-km-high mound features to the south, probably composed of H2O, are young geologically as inferred by light cratering and superposition relationships. Their origin, and what drove their formation so late in Solar System history, is under investigation. The dynamic remolding of landscapes by volatile transport seen on Pluto is not unambiguously evident in the mapping of Charon. Charon does, however, display a large resurfaced plain and globally engirdling extensional tectonic network attesting to its early endogenic vigor.

scholarly journals TOPOGRAPHIC MAPPING OF PLUTO AND CHARON USING NEW HORIZONS DATA

2016 ◽  
Vol XLI-B4 ◽  
pp. 487-489
Author(s):  
P. M. Schenk ◽  
R. A. Beyer ◽  
J. M. Moore ◽  
J. R. Spencer ◽  
W. B. McKinnon ◽  
...  
Keyword(s):  
High Resolution ◽  
Viscous Flow ◽  
High Impact ◽  
Impact Craters ◽  
Topographic Maps ◽  
Topographic Mapping ◽  
New Horizons ◽  
Rolling Plains

New Horizons 2015 flyby of the Pluto system has resulted in high-resolution topographic maps of Pluto and Charon, the most distant objects so mapped. DEM’s over ~30% of each object were produced at 100-300 m vertical and 300-800 m spatial resolutions, in hemispheric maps and high-resolution linear mosaics. Both objects reveal more relief than was observed at Triton. The dominant 800-km wide informally named Sputnik Planum bright ice deposit on Pluto lies in a broad depression 3 km deep, flanked by dispersed mountains 3-5 km high. Impact craters reveal a wide variety of preservation states from pristine to eroded, and long fractures are several km deep with throw of 0-2 km. Topography of this magnitude suggests the icy shell of Pluto is relatively cold and rigid. Charon has global relief of at least 10 km, including ridges of 2-3 km and troughs of 3-5 km of relief. Impact craters are up to 6 km deep. Vulcan Planum consists of rolling plains and forms a topographic moat along its edge, suggesting viscous flow.

Uranus after Voyager 2 and the Origin of the Solar System

1986 ◽  
Vol 6 (4) ◽  
pp. 394-402 ◽  
Author(s):  
A. J. R. Prentice
Keyword(s):  
Solar System ◽  
Clathrate Hydrate ◽  
Turbulence Parameter ◽  
Convective Turbulence ◽  
Satellite Systems ◽  
Equatorial Radius ◽  
Voyager 2 ◽  
Uranian Satellites

AbstractThe discoveries made by the Voyager 2 spacecraft at Uranus in January 1986 are discussed in the light of the modern Laplacian theory for the formation of the solar system. Various accounts of this theory, which has as its basis the concept of supersonic convective turbulence, have been presented at previous meetings of the ASA (Prentice 1977, 1979, 1981a). The most important confirmation by Voyager was the discovery of 2 new satellite groups near orbital radii 2½ RUand 3½ RU(RU= Uranus’ equatorial radius = 26, 200 km), as first predicted in 1977. The discovery that the densities of the Uranian satellites are consistent with these bodies having condensed in a single compositional class, consisting of anhydrous rock, NH3ice and CH4.6H2O clathrate hydrate in normal solar proportions, confirms the hypothesis that the chemistry of all planetary/regular satellite systems are accounted for by a single choice of the turbulence parameter, namely β = 0.107 ±0.001. The implication of the Voyager data for the origin of comets is also discussed.

Icy Satellites: Geological Evolution and Surface Processes

2009 ◽  
pp. 637-681 ◽  
Author(s):  
Ralf Jaumann ◽  
Roger N. Clark ◽  
Francis Nimmo ◽  
Amanda R. Hendrix ◽  
Bonnie J. Buratti ◽  
...  
Keyword(s):  
Surface Processes ◽  
Icy Satellites ◽  
Geological Evolution

scholarly journals Comet composition and Lab

2015 ◽  
Vol 11 (A29A) ◽  
pp. 227-227
Author(s):  
Dominique Bockelée-Morvan
Keyword(s):  
Solar System ◽  
Small Worlds ◽  
Icy Satellites ◽  
Small Bodies ◽  
New Horizons ◽  
Dwarf Planets ◽  
Cassini Mission ◽  
Solar System Bodies ◽  
Geochemical Analyses ◽  
Comet 67P

The XXIX IAU General Assembly took place during the golden year of the exploration of small solar system bodies. With the Rosetta ESA mission around comet 67P, NASA Dawn and New Horizons missions nearby dwarf planets Ceres and Pluto, respectively, and the NASA/Cassini mission in Saturn neighborhood, year 2015 marked an important step towards further understanding of small solar system bodies. On August 11-13, Focus meeting 9 "Highlights in the exploration of small worlds" gathered scientists of all over the world to present and discuss the spectacular results obtained from these missions, as well as recent achievements obtained from past missions, comprehensive spectroscopic surveys from space (e.g., Herschel, NEOWISE, Gaia), ground-based observations, and geochemical analyses. This meeting was also the opportunity to discuss the state of our understanding of the nature of the various populations of small bodies in the Solar System, including icy satellites, in a cosmo-chemistry perspective.

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