Your search keyword '"cryovolcanism"' showing total 58 results

1. The challenges of driving Charon's cryovolcanism from a freezing ocean

Author

Alyssa Rose Rhoden, Maxwell L. Rudolph, and Michael Manga

Subjects

Space and Planetary Science, Astronomy and Astrophysics

Published

2023

2. Differentiation and cryovolcanism on Charon: A view before and after New Horizons

Author

Steven J. Desch and Marc Neveu

Subjects

Radiogenic nuclide, Younger age, New horizons, 010504 meteorology & atmospheric sciences, Astronomy, Astronomy and Astrophysics, 01 natural sciences, Extensional definition, Astrobiology, Pluto, Space and Planetary Science, Lithosphere, 0103 physical sciences, Vulcan, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Before the arrival of the New Horizons probe at the Pluto-Charon system, we developed a series of models that predicted that Kuiper Belt Objects, even as small and as cold as Charon, have experienced internal ice-rock differentiation and possibly cryovolcanism. Confronting these predictions is a wide array of spectroscopy, imagery, and other data from New Horizons. In this article we compare the predictions against the new observations, and find that they largely support the expected history of the Pluto system and the evolution of Charon. Following the collision of two partially differentiated impactors with radii ≈1000 km, a disk of material formed around Pluto, from which Charon and Pluto’s other moons formed. Because the impactors did not completely differentiate, the disk contained rocky material from their crusts, explaining the moons’ different densities and compositions. Long-lived radionuclides in Charon, assisted by ammonia antifreeze in the ice, melted ice and created a subsurface ocean that eventually refroze ≈ 1.7 − 2.5 Gyr ago. The freezing of this ocean would have created extensional stresses that possibly created Serenity Chasma, and could have led to widespread resurfacing, explaining the apparently younger age of Vulcan Planum. Buildup of radiogenic heat then created a second, smaller ocean that refroze 0.5–1.7 Gyr ago. As it froze, cryovolcanism would have been enabled, possibly creating Kubrick Mons. Charon’s “moated mountains” such as Kubrick Mons have a natural explanation as cryovolcanoes depressing a thin lithosphere over a cryomagma chamber. We offer further predictions about other aspects of Charon’s surface. Our previous predictions that Charon is a world shaped by geological activity have been largely borne out by New Horizons observations.

Published

2017

3. A lobate feature adjacent to a double ridge on Ariel: Formed by cryovolcanism or mass wasting?

Author

Richard Cartwright and Chloe B. Beddingfield

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Feature (archaeology), Astronomy and Astrophysics, Mass wasting, Diapir, 01 natural sciences, Head (geology), Dome (geology), Tectonics, Space and Planetary Science, Ridge, 0103 physical sciences, Petrology, Coefficient of friction, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

We identified a large-scale lobate feature that is proximal to a double ridge on Ariel. We analyzed the morphology of this feature to investigate whether it was formed by cryovolcanism or mass wasting. Our results show that the head of the lobate feature is adjacent to a topographically elevated dome on the double ridge, which may have formed via extrusion and emplacement of cryolava in this location. We find that the coefficient of friction of the material that formed the lobate feature is more consistent with a cryovolcanic flow than either a dry or liquid-aided mass wasting flow. Similarly, the estimated yield strength for the neck and terminus of this feature is similar to geologic features that contained some liquid during formation. Alternatively, upwelling of material, in an ascending diapir, could also explain the morphology of this lobate feature, in particular its topographically elevated terminus, which is higher standing than its neck. Higher resolution images are needed to assess the surface texture of the lobate feature to further investigate whether it formed via flowing cryolava or diapirism. Furthermore, without higher spatial resolution images, the possibility of a mass wasting origin for the lobate feature cannot be ruled out and warrants further investigation. The possible presence of cryovolcanic features on Ariel supports the interpretation that this moon is a candidate ocean world that has, or had, a subsurface liquid water layer beneath its icy exterior.

Published

2021

4. Recent cryovolcanism in Virgil Fossae on Pluto

Author

Catherine B. Olkin, Kelsi N. Singer, Richard Cartwright, Kimberly Ennico, Ross A. Beyer, Richard P. Binzel, Isamu Matsuyama, Kirby Runyon, Oliver L. White, James Tuttle Keane, Carey M. Lisse, Leslie A. Young, William B. McKinnon, Jeffrey M. Moore, Dale P. Cruikshank, S. Alan Stern, Dimitra Atri, G. Randall Gladstone, Alissa M. Earle, Bernard Schmitt, Harold A. Weaver, Orkan M. Umurhan, Tanguy Bertrand, John R. Spencer, Scott A. Sandford, Stuart J. Robbins, Cristina M. Dalle Ore, William M. Grundy, Jason C. Cook, NASA Ames Research Center (ARC), Institut de Planétologie et d'Astrophysique de Grenoble (IPAG), Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Grenoble (OSUG ), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national des sciences de l'Univers (INSU - CNRS)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), California Institute of Technology (CALTECH), Johns Hopkins University Applied Physics Laboratory [Laurel, MD] (APL), New York University [Abu Dhabi], NYU System (NYU), Department of Earth and Planetary Sciences [St Louis], Washington University in Saint Louis (WUSTL), Southwest Research Institute [Boulder] (SwRI), Lowell Observatory [Flagstaff], Pinhead Institute, Massachusetts Institute of Technology (MIT), and Southwest Research Institute [San Antonio] (SwRI)

Subjects

010504 meteorology & atmospheric sciences, Ices, Trough (geology), [SDU.ASTR.EP]Sciences of the Universe [physics]/Astrophysics [astro-ph]/Earth and Planetary Astrophysics [astro-ph.EP], Organic chemistry, 01 natural sciences, Astrobiology, Impact crater, Lithosphere, 0103 physical sciences, 14. Life underwater, True polar wander, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, volcanism, Pluto, Interiors, Astronomy and Astrophysics, Tholin, Graben, Surface, 13. Climate action, Space and Planetary Science, IR spectroscopy, Formation and evolution of the Solar System

Abstract

International audience; The Virgil Fossae region on Pluto exhibits three spatially coincident properties that are suggestive of recent cryovolcanic activity over an area approximately 300 by 200 km. Situated in the fossae troughs or channels and in the surrounding terrain are exposures of H2O ice in which there is entrained opaque red-colored matter of unknown composition. The H2O ice is also seen to carry spectral signatures at 1.65 and 2.2 μm of NH3 in some form, possibly as a hydrate, an ammoniated salt, or some other compound. Model calculations of NH3 destruction in H2O ice by galactic cosmic rays suggest that the maximum lifetime of NH3 in the uppermost meter of the exposed surface is ~109 years, while considerations of Lyman-α ultraviolet and solar wind charged particles suggest shorter timescales by a factor of 10 or 10000. Thus, 109 y is taken as an upper limit to the age of the emplacement event, and it could be substantially younger. The red colorant in the ammoniated H2O in Virgil Fossae and surroundings may be a macromolecular organic material (tholin) thought to give color to much of Pluto's surface, but probably different in composition and age. Owing to the limited spectral range of the New Horizons imaging spectrometer and the signal precision of the data, apart from the H2O and NH3 signatures there are no direct spectroscopic clues to the chemistry of the strongly colored deposit on Pluto. We suggest that the colored material was a component of the fluid reservoir from which the material now on the surface in this region was erupted. Although other compositions are possible, if it is indeed a complex organic material it may incorporate organics inherited from the solar nebula, further processed in a warm aqueous environment inside Pluto. A planet-scale stress pattern in Pluto's lithosphere induced by true polar wander, freezing of a putative interior ocean, and surface loading has caused fracturing in a broad arc west of Sputnik Planitia, consistent with the structure of Virgil Fossae and similar extensional features. This faulting may have facilitated the ascent of fluid in subsurface reservoirs to reach the surface as flows and as fountains of cryoclastic materials, consistent with the appearance of colored, ammoniated H2O ice deposits in and around Virgil Fossae. Models of a cryoflow emerging from sources in Virgil Fossae indicate that the lateral extent of the flow can be several km (Umurhan et al., 2019). The deposit over the full length (> 200 km) of the main trough in the Virgil Fossae complex and extending through the north rim of Elliot crater and varying in elevation over a range of ~2.5 km, suggests that it debouched from multiple sources, probably along the length of the strike direction of the normal faults defining the graben. The source or sources of the ammoniated H2O are one or more subsurface reservoirs that may or may not connect to the global ocean postulated for Pluto's interior. Alternatives to cryovolcanism in producing the observed characteristics of the region around Virgil Fossae are explored in the discussion section of the paper.

Published

2019

5. Ammonia-water freezing as a mechanism for recent cryovolcanism on Pluto

Author

Richard P. Binzel and Craig Martin

Subjects

geography, geography.geographical_feature_category, New horizons, 010504 meteorology & atmospheric sciences, Astronomy and Astrophysics, Crust, Geologic map, 01 natural sciences, Overpressure, Pluto, Tectonics, Space and Planetary Science, 0103 physical sciences, Liquid flow, Ravine, Petrology, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

NASA's New Horizons flyby of the Pluto-Charon system in 2015 exposed a multitude of geologically active terrains on the surface of Pluto. Possible evidence of cryovolcanism has been reported in association with crustal scale extensional tectonic structures at Virgil Fossae and at two large circular mountains, informally referred to as Wright Mons and Piccard Mons. Our detailed geologic mapping of Wright Mons and the surrounding region reveals additional circular mounds overlying the main edifice and narrow ravines emanating from the summit, possibly produced by liquid flow. We model the overpressure generated during the freezing of a mixed ammonia-water liquid inside an enclosed chamber in Pluto's ice crust and in a global subsurface ocean. We consider scenarios spanning the possible range of Pluto's ammonia abundance and conclude that stresses generated due to freezing-induced pressurization can exceed the tensile strength of ice and create fractures for the liquid to escape. Our results suggest that freezing in a crustal chamber and the subsurface ocean are both viable mechanisms for cryovolcanism on Pluto and may explain the morphological variety of cryovolcanic formations observed by New Horizons.

Published

2021

6. Discrete sources of cryovolcanism on the nucleus of Comet 29P/Schwassmann–Wachmann and their origin

Author

Richard Miles

Subjects

Physics, Rotation period, 010504 meteorology & atmospheric sciences, Direct insolation, Comet, Astronomy, Astronomy and Astrophysics, Crust, Astrophysics, 01 natural sciences, Cosmochemistry, Space and Planetary Science, Sidereal time, Solar time, 0103 physical sciences, Longitude, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

Evidence for long-lived sources of cryovolcanism on the nucleus of the Comet 29P/Schwassmann–Wachmann has been found from a study of its times of outburst ( t 0 ) and the morphological development of inner coma structures. Analysis of data from the Minor Planet Center observations archive spanning 2002–2014 and other observations have yielded 64 outburst times of mainly well-observed events with a median timing uncertainty of 0.40 d. Outbursts comprise largely (i) isolated explosive events; or (ii) multiple outbursts occurring typically within 5–15 d of each other. On rare occasions, a form of continuous or gradually increasing activity is manifest, appearing to be the result of a series of mini-outbursts. Quasi-periodicity in t 0 is manifested as an excess of outbursts every 52–60 d, along with a paucity of events every ∼30 d and ∼90 d. Seasonal changes in activity are evident from the temporal analysis of the outburst data. An unambiguous periodicity of 57.6 ± 0.4 d has been found in the times of 26 outbursts during 2010–2014, with all active sources at that time localised within a longitude span of ∼135–150°. Cluster analysis of t 0 data for 2002–2010 and 2010–2014, and HST imaging from 1996 confirm and refine the apparent periodicity, indicating that outbursts appear to be grouped in longitude centred on at least 6 circumferential locations. Sources of activity generally persist for at least 10–20 yr, and some appear discrete in nature, able to re-outburst after a single day–night cycle. Given that outbursts are triggered by solar heating, the analysis yields a value for the mean solar day of 57.71 ± 0.06 d, equivalent to a sidereal rotation period of 57.09 ± 0.06 d, assuming the more probable prograde direction of spin. A novel outburst mechanism is outlined in which some cometary ices, principally solid CH 4 , confined under pressure (>12 kPa) beneath a stabilisation crust, begin to melt and absorb supervolatile gases, mainly CO and N 2 . These gases liberate considerable heat (5–7 kJ mol −1 ) via their enthalpy of solution inducing further melting deep within the nucleus where direct insolation heating is absent. This gas-solute process is most active near the solid–liquid interface, where the solvent temperature is lowest and gas solubility is highest. An outburst occurs when insolation heating of the crust above a gas-laden subsurface reservoir softens paraffinic hydrocarbons and causes a crustal plate to dislodge under the accumulated gas pressure, the sudden release of which provokes the explosive ex-solution of dissolved gases, principally CO, propelling entrained dust and debris into space. Fissures reseal as the plate sinks back under the gravitational influence of the large nucleus and the adhesive, waxy hydrocarbon fraction solidifies, permitting a new outburst cycle to begin. A detailed account of the gas ex-solution mechanism is the subject of a partner paper (Miles, R. [2015]. Icarus).

Published

2016

7. Testing the cryovolcanism and plate bending hypotheses for Charon's smooth plains

Author

Geoffrey C. Collins and Madison E. Borrelli

Subjects

010504 meteorology & atmospheric sciences, Correlation coefficient, Lava, Flow (psychology), Front (oceanography), Elevation, Astronomy and Astrophysics, Terrain, Bending of plates, 01 natural sciences, Space and Planetary Science, 0103 physical sciences, Vulcan, 010303 astronomy & astrophysics, Geomorphology, Geology, 0105 earth and related environmental sciences

Abstract

Topographic moats are found at the edges of Charon's Vulcan Planitia, both where the plains meet the higher elevation terrain in Oz Terra, and surrounding isolated mountains within the smooth plains. The curved edges of the moats have been hypothesized to represent either the front of a cryolava flow from the emplacement of the plains material, or the result of elastic flexure of the plains surface due to the load of adjacent mountains or sinking crustal blocks. We tested both of these hypotheses by taking topographic profiles across the moats and comparing the observations to theoretical predictions from two lava flow models and two plate bending models. The algorithm we used returns a correlation coefficient as well as the parameter values for the theoretical model necessary to match the topography. Our results show that the plate bending models provided the best fits for the topography, though the lava flow models provided good matches for a few profiles. Our results for elastic thickness of ~1 km for a continuous plate or ~3 km for a broken plate are similar to results previously derived at Serenity Chasma. The values obtained for Bingham yield strength of ~10 kPa are also consistent with previous results from hypothesized cryovolcanic material on Ariel and Charon.

Published

2021

8. Cryovolcanism as a cause of changes in the brightness of Comet 174P/Echeclus

Author

M. Wesołowski

Subjects

Physics, Brightness, 010504 meteorology & atmospheric sciences, Astrophysics::High Energy Astrophysical Phenomena, Comet, Astronomy and Astrophysics, Astrophysics, 01 natural sciences, Space and Planetary Science, Physics::Space Physics, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Sublimation (phase transition), Astrophysics::Earth and Planetary Astrophysics, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

The paper presents an analysis of the real change in brightness of comet 174P/Echeclus (60558 Echeclus), using the cryovolcanism mechanism. The relationship between the mass ejected during the outburst and the active surface during quiet sublimation is also presented. It has been shown that the mass ejected is one of the key parameters determining the change in the brightness of a comet. This assumption was also confirmed by many years of observations of comets during their outbursts.

Published

2020

9. Prerequisites for explosive cryovolcanism on dwarf planet-class Kuiper belt objects

Author

Marc Neveu, Christopher R. Glein, Everett L. Shock, and Steven J. Desch

Subjects

Pluto, Explosive material, Space and Planetary Science, Dwarf planet, Astronomy and Astrophysics, Crust, Volcanism, Enceladus, Hydrothermal circulation, Geology, Geochemical modeling, Astrobiology

Abstract

Explosive extrusion of cold material from the interior of icy bodies, or cryovolcanism, has been observed on Enceladus and, perhaps, Europa, Triton, and Ceres. It may explain the observed evidence for a young surface on Charon (Pluto’s surface is masked by frosts). Here, we evaluate prerequisites for cryovolcanism on dwarf planet-class Kuiper belt objects (KBOs). We first review the likely spatial and temporal extent of subsurface liquid, proposed mechanisms to overcome the negative buoyancy of liquid water in ice, and the volatile inventory of KBOs. We then present a new geochemical equilibrium model for volatile exsolution and its ability to drive upward crack propagation. This novel approach bridges geophysics and geochemistry, and extends geochemical modeling to the seldom-explored realm of liquid water at subzero temperatures. We show that carbon monoxide (CO) is a key volatile for gas-driven fluid ascent; whereas CO_2 and sulfur gases only play a minor role. N_2, CH_4, and H_2 exsolution may also drive explosive cryovolcanism if hydrothermal activity produces these species in large amounts (a few percent with respect to water). Another important control on crack propagation is the internal structure: a hydrated core makes explosive cryovolcanism easier, but an undifferentiated crust does not. We briefly discuss other controls on ascent such as fluid freezing on crack walls, and outline theoretical advances necessary to better understand cryovolcanic processes. Finally, we make testable predictions for the 2015 New Horizons flyby of the Pluto-Charon system.

Published

2015

10. Old Faithful model for radiolytic gas-driven cryovolcanism at Enceladus

Author

Steven J. Sturner, John F. Cooper, Edward C. Sittler, Paul D. Cooper, and Abigail Rymer

Subjects

Jupiter, Outgassing, Space and Planetary Science, Environmental science, Astronomy and Astrophysics, Blanketing, Ejecta, Icy moon, Enceladus, Regolith, Plume, Astrobiology

Abstract

A new model is presented on how chemically driven cryovolcanism might contribute to episodic outgassing at the icy moon Enceladus and potentially elsewhere including Europa and Kuiper Belt Objects. Exposed water ices can become oxidized from radiolytic chemical alteration of near-surface water ice by space environment irradiation. In contact with primordially abundant reductants such as NH3, CH4, and other hydrocarbons, the product oxidants can react exothermically to produce volatile gases driving cryovolcanism via gas-piston forces on any subsurface liquid reservoirs. Radiolytic oxidants such as H2O2 and O2 can continuously accumulate deep in icy regoliths and be conveyed by rheological flows to subsurface chemical reaction zones over million-year time scales indicated by cratering ages for active regions of Enceladus and Europa. Surface blanketing with cryovolcanic plume ejecta would further accelerate regolith burial of radiolytic oxidants. Episodic heating from transient gravitational tides, radioisotope decay, impacts, or other geologic events might occasionally accelerate chemical reaction rates and ignite the exothermic release of cumulative radiolytic oxidant energy. The time history for the suggested "Old Faithful" model of radiolytic gas-driven cryovolcanism at Enceladus and elsewhere therefore consists of long periods of chemical energy accumulation punctuated by much briefer episodes of cryovolcanic activity. The most probable sequence for detection of activity in the current epoch is a long evolutionary phase of slow but continuous oxidant accumulation over billions of years followed by continuous but variable high activity over the past 10(exp 7)-10(exp 8) years. Detectable cryovolcanic activity could then later decline due to near-total oxidation of the rheologically accessible ice crust and depletion the accessible reductant abundances, as may have already occurred for Europa in the more intense radiation environment of Jupiter's magnetosphere. Astrobiological potential of Enceladus could correspondingly be higher than at Europa due to a less extreme state of oxidation and greater residual abundance of organics.

Published

2009

11. Thermal evolution of Kuiper belt objects, with implications for cryovolcanism

Author

Steven J. Desch, Jason C. Cook, T. C. Doggett, and Simon B. Porter

Subjects

Pluto, Space and Planetary Science, Neptune, Thermal, Melting point, Astronomy, Astronomy and Astrophysics, Crust, Present day, Geology, Astrobiology

Abstract

We investigate the internal thermal evolution of Kuiper belt objects (KBOs), small (radii 2500 kg m − 3 ) bodies orbiting beyond Neptune, focusing on Pluto's moon Charon in particular. Our calculations are time-dependent and account for differentiation. We review evidence for ammonia hydrates in the ices of KBOs, and include their effects on the thermal evolution. A key finding is that the production of the first melt, at the melting point of ammonia dihydrate, ≈ 176 K , triggers differentiation of rock and ice. The resulting structure comprises a rocky core surrounded by liquids and ice, enclosed within a >100-km thick undifferentiated crust of rock and ice. This structure is especially conducive to the retention of subsurface liquid, and bodies the size of Charon or larger (radii >600 km) are predicted to retain some subsurface liquid to the present day. We discuss the possibility that this liquid can be brought to the surface rapidly via self-propagating cracks. We conclude that cryovolcanism is a viable process expected to affect the surfaces of large KBOs including Charon.

Published

2009

12. Near‐Infrared Spectroscopy of Charon: Possible Evidence for Cryovolcanism on Kuiper Belt Objects

Author

Jason C. Cook, Chadwick A. Trujillo, Ted L. Roush, Thomas R. Geballe, and Steven J. Desch

Subjects

Physics, Space and Planetary Science, Planet, Near-infrared spectroscopy, Astronomy, Astronomy and Astrophysics, Near-Infrared Spectrometry, Visible radiation, Water ice, Spectral line

Abstract

We present the first reported adaptive optics spectra of Charon in the H and K bands, which examine the anti-Pluto and sub-Pluto hemispheres. The ice temperature is estimated at 40-50 K, based on the 1.65 μm feature of crystalline water ice. We obtain the most accurate profiles of the 2.21 μm feature and confirm that the feature is due to hydrated ammonia. We attribute hemispheric differences in the feature's profile to different hydration states. We calculate the rate at which crystalline water ice is amorphized by solar UV/visible radiation, finding that at the depths probed by H and K observations (≈350 μm), the e-folding time to amorphize ice is (3-5) × 104 yr. This implies Charon's ice crystallized from a melt, or has been heated to 90 K, during the last ~105 yr. The extent of the crystalline water ice and the short timescales involved argue that surface renewal is necessary, a conclusion reinforced by the presence of ammonia hydrates. We investigate possible mechanisms for surface renewal and conclude that cryovolcanism is the most likely.

Published

2007

13. Cryovolcanism and the Recent Flow of Liquid Water on Mars

Author

Eric Gaidos

Subjects

Canyon, geography, geography.geographical_feature_category, Water on Mars, Lead (sea ice), Astronomy and Astrophysics, Aquifer, Crust, Mars Exploration Program, Volcano, Impact crater, Space and Planetary Science, Petrology, Geology

Abstract

The surface of Mars is too cold and dry to permit stable liquid water, yet fresh, apparently water-carved gullies and seepage features have been identified in high-resolution imaging of canyon and crater walls by the Mars Global Surveyor spacecraft. Here, a model of nonequilibrium hydrological activity and liquid water cryovolcanism explains the paradoxical appearance and observed properties of these landforms: Aquifers within a porous crust are confined by growing ice and impermeable volcanic layers or basement rock. Freeze–thaw cycles driven by changes in heat flow or climate create high ambient pore pressures and lead to catastrophic expulsion of water through cracks to the surface. The gullies are thus indicators of the geologic and thermal state of the crust, not the present surface environment. Investigations of deposits formed by this cryovolcanism are a means of probing the deep subsurface of Mars for potential biological activity.

Published

2001

14. Ammonium sulfate on Titan: Possible origin and role in cryovolcanism

Author

Peter Grindrod, S.K. Trickett, Andrew Dominic Fortes, and Lidunka Vočadlo

Subjects

Carbon dioxide clathrate, Ammonium sulfate, Methane clathrate, Clathrate hydrate, Ice Ih, Mineralogy, Astronomy and Astrophysics, Mantle (geology), Methane, chemistry.chemical_compound, chemistry, Space and Planetary Science, Amorphous ice, Geology

Abstract

We model the chemical evolution of Titan, wherein primordial NH3 reacts with sulfate-rich brines leached from the silicate core during its hydration. The resulting differentiated body consists of a serpentinite core overlain by a high-pressure ice VI mantle, a liquid layer of aqueous ammonium sulfate, and a heterogeneous shell of methane clathrate, low-pressure ice Ih and solid ammonium sulfate. Cooling of the subsurface ocean results in underplating of the outer shell with ice Ih; this gravitationally unstable system can produce compositional plumes as ice Ih ascends buoyantly. Ice plumes may aid in advection of melt pockets through the shell and, in combination with surface topography, provide the necessary hydraulic pressure gradients to drive such melts to the surface. Moreover, contact between the magma and wall rock (methane clathrate) will allow some methane to dissolve in the magma, as well as eroding fragments of wall rock that can be transported as xenoliths. Upon rising to the clathrate decomposition depth (∼ 2 MPa, or 1700 m), the entrained xenoliths will break down to ice + methane gas, powering highly explosive eruptions with lava fountains up to several kilometers high. Hence we predict that Titan is being resurfaced by cryoclastic ash consisting of ice and ammonium sulfate (or its tetrahydrate), providing an abundance of sedimentary grains, a potential source of bedload for fluvial transport and erosion, and of sand-sized material for aeolian transport and dune-building. The infrared reflectance spectrum of ammonium sulfate makes it a plausible candidate for the 5 μm-bright material on Titan's surface. © 2006 Elsevier Inc. All rights reserved.

Published

2007

15. Active Cryovolcanism on Europa?

Author

J. R. Spencer, Britney E. Schmidt, Kevin P. Hand, Melissa A. McGrath, William B. Sparks, S. E. Deustua, and Misty Cracraft

Subjects

Earth and Planetary Astrophysics (astro-ph.EP), Physics, Brightness, Radiometer, 010504 meteorology & atmospheric sciences, FOS: Physical sciences, Astronomy and Astrophysics, Geophysics, Moment of inertia, 01 natural sciences, Plume, Heat flux, Space and Planetary Science, Brightness temperature, 0103 physical sciences, Thermal, 010303 astronomy & astrophysics, Heat flow, Astrophysics - Earth and Planetary Astrophysics, 0105 earth and related environmental sciences

Abstract

Evidence for plumes of water on Europa has previously been found using the Hubble Space Telescope (HST) using two different observing techniques. Roth et al. (2014) found line emission from the dissociation products of water. Sparks et al. (2016) found evidence for off-limb continuum absorption as Europa transited Jupiter. Here, we present a new transit observation of Europa that shows a second event at the same location as a previous plume candidate from Sparks et al. (2016), raising the possibility of a consistently active source of erupting material on Europa. This conclusion is bolstered by comparison with a nighttime thermal image from the Galileo Photopolarimeter-Radiometer (PPR) which shows a thermal anomaly at the same location, within the uncertainties (Spencer et al. 1999). The anomaly has the highest observed brightness temperature on the Europa nightside. If heat flow from a subsurface liquid water reservoir causes the thermal anomaly, its depth is ~1.8-2 km, under simple modeling assumptions, consistent with scenarios in which a liquid water reservoir has formed within a thick ice shell. Models that favor thin regions within the ice shell that connect directly to the ocean, however, cannot be excluded, nor modifications to surface thermal inertia by subsurface activity. Alternatively, vapor deposition surrounding an active vent could increase the thermal inertia of the surface and cause the thermal anomaly. This candidate plume region may offer a promising location for an initial characterization of Europa's internal water and ice and for seeking evidence of Europa's habitability. ~, Comment: 14 pages, 2 figures

Published

2017

16. Cryovolcanism on the icy satellites

Author

Jeffrey S. Kargel

Subjects

Basalt, geography, Cinder cone, geography.geographical_feature_category, Lava, Clathrate hydrate, Uranus, Lava dome, Astronomy and Astrophysics, Astrobiology, Volcano, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), Formation and evolution of the Solar System, Geology

Abstract

Evidence of past cryovolcanism is widespread and extremely varied on the icy satellites. Some cryovolcanic landscapes, notably on Triton, are similar to many silicate volcanic terrains, including what appear to be volcanic rifts, calderas and solidified lava lakes, flow fields, breached cinder cones or stratovolcanoes, viscous lava domes, and sinuous rilles. Most other satellites have terrains that are different in the important respect that no obvious volcanoes are present. The preserved record of cryovolcanism generally is believed to have formed by eruptions of aqueous solutions and slurries. Even Triton's volcanic crust, which is covered by nitrogen-rich frost, is probably dominated by water ice. Nonpolar and weakly polar molecular liquids (mainly N2, CH4, CO, CO2, and Ar), may originate by decomposition of gas-clathrate hydrates and may have been erupted on some icy satellites, but without water these substances do not form rigid solids that are stable against sublimation or melting over geologic time. Triton's plumes, active at the time of Voyager 2's flyby, may consist of multicomponent nonpolar gas mixtures. The plumes may be volcanogenic fumaroles or geyserlike emissions powered by deep internal heating, and, thus, the plumes may be indicating an interior that is still cryomagmatically active; or Triton's plumes may be powered by solar heating of translucent ices very near the surface. The Uranian and Neptunian satellites Miranda, Ariel, and Triton have flow deposits that are hundreds to thousands of meters thick (implying highly viscous lavas); by contrast, the Jovian and Saturnian satellites generally have plains-forming deposits composed of relatively thin flows whose thicknesses have not been resolved in Voyager images (thus implying relatively low-viscosity lavas). One possible explanation for this inferred rheological distinction involves a difference in volatile composition of the Uranian and Neptunian satellites on one hand and of the Jovian and Saturnian satellites on the other hand. Perhaps the Jovian and Saturnian satellites tend to have relatively "clean" compositions with water ice as the main volatile (ammonia and water-soluble salts may also be present). The Uranian and Neptunian satellites may possess large amounts of a chemically unequilibrated comet-like volatile assemblage, including methanol, formaldehyde, and a host of other highly water- and ammonia-water-soluble constituents and gas clathrate hydrates. These two volatile mixtures would produce melts that differ enormously in viscosity The geomorphologic similarity in the products of volcanism on Earth and Triton may arise partly from a rheological similarity of the ammonia-water-methanol series of liquids and the silicate series ranging from basalt to dacite. An abundance of gas clathrate hydrates hypothesized to be contained by the satellites of Uranus and Neptune could contribute to evidence of explosive volcanism on those objects.

Published

1994

17. Identification of cryovolcanism on Titan using fuzzy cognitive maps

Author

Michael P. Bishop, Jeffrey S. Kargel, Roberto Furfaro, Jonathan I. Lunine, and Wolfgang Fink

Subjects

Synthetic aperture radar, Cognitive model, business.industry, Computer science, Astronomy and Astrophysics, computer.software_genre, Automation, Fuzzy logic, Robotic spacecraft, Fuzzy cognitive map, law.invention, Orbiter, Space and Planetary Science, law, Data mining, Radar, business, computer, Remote sensing

Abstract

Future planetary exploration of Titan will require higher degrees of on-board automation, including autonomous determination of sites where the probability of significant scientific findings is the highest. In this paper, a novel Artificial Intelligence (AI) method for the identification and interpretation of sites that yield the highest potential of cryovolcanic activity is presented. We introduce the theory of fuzzy cognitive maps (FCM) as a tool for the analysis of remotely collected data in planetary exploration. A cognitive model embedded in a fuzzy logic framework is constructed via the synergistic interaction of planetary scientists and AI experts. As an application example, we show how FCM can be employed to solve the challenging problem of recognizing cryovolcanism from Synthetic Aperture Radar (SAR) Cassini data. The fuzzy cognitive map is constructed using what is currently known about cryovolcanism on Titan and relies on geological mapping performed by planetary scientists to interpret different locales as cryovolcanic in nature. The system is not conceived to replace the human scientific interpretation, but to enhance the scientists’ ability to deal with large amounts of data, and it is a first step in designing AI systems that will be able, in the future, to autonomously make decisions in situations where human analysis and interpretation is not readily available or could not be sufficiently timely. The proposed FCM is tested on Cassini radar data to show the effectiveness of the system in reaching conclusions put forward by human experts and published in the literature. Four tests are performed using the Ta SAR image (October 2004 fly-by). Two regions (i.e. Ganesa Macula and the lobate high backscattering region East of Ganesa) are interpreted by the designed FCM as exhibiting cryovolcanism in agreement with the initial interpretation of the regions by Stofan et al. (2006). Importantly, the proposed FCM is shown to be flexible and adaptive as new data and knowledge are acquired during the course of exploration. Subsequently, the FCM has been modified to include topographic information derived from SAR stereo data. With this additional information, the map concludes that Ganesa Macula is not a cryovolcanic region. In conclusion, the FCM methodology is shown to be a critical and powerful component of future autonomous robotic spacecraft (e.g., orbiter(s), balloon(s), surface/lake lander(s), rover(s)) that will be deployed for the exploration of Titan.

Published

2010

18. Bright carbonate surfaces on Ceres as remnants of salt-rich water fountains

Author

Andreas Nathues, Ralf Jaumann, Ottavian Ruesch, Adrian Neesemann, Margaret E. Landis, Julie Castillo-Rogez, Katrin Krohn, F. Preusker, T. Roatsch, Lynnae C. Quick, Jennifer E.C. Scully, David A. Williams, Shane Byrne, Lucy A. McFadden, Mark V. Sykes, Carol A. Raymond, Ondřej Čadek, P. M. Schenk, Harald Hiesinger, Christopher T. Russell, Michael T. Bland, Petr Brož, Michael M. Sori, and Katharina A. Otto

Subjects

asteroids, 010504 meteorology & atmospheric sciences, water, Doming, cryovolcanism, Mineralogy, carbonates, CERES, 01 natural sciences, law.invention, bright spots, carbonate, chemistry.chemical_compound, Impact crater, law, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Flash freezing, Liquid viscosity, Astronomy and Astrophysics, water-ice, chemistry, Space and Planetary Science, Carbonate, Extrusion, Sodium carbonate, small bodies, Geology, Lofting

Abstract

Vinalia and Cerealia Faculae are bright and salt-rich localized areas in Occator crater on Ceres. The predominance of the near-infrared signature of sodium carbonate on these surfaces suggests their original material was a brine. Here we analyze Dawn Framing Camera's images and characterize the surfaces as composed of a central structure, either a possible depression (Vinalia) or a central dome (Cerealia), and a discontinuous mantling. We consider three materials enabling the ascent and formation of the faculae: ice ascent with sublimation and carbonate particle lofting, pure gas emission entraining carbonate particles, and brine extrusion. We find that a mechanism explaining the entire range of morphologies, topographies, as well as the common composition of the deposits is brine fountaining. This process consists of briny liquid extrusion, followed by flash freezing of carbonate and ice particles, particle fallback, and sublimation. Subsequent increase in briny liquid viscosity leads to doming. Dawn observations did not detect currently active water plumes, indicating the frequency of such extrusions is longer than years.

Published

2019

19. The unique geomorphology and structural geology of the Haulani crater of dwarf planet Ceres as revealed by geological mapping of equatorial quadrangle Ac-6 Haulani

Author

E. Kersten, I. von der Gathen, Katrin Krohn, Frank Preusker, Katharina A. Otto, Andrea Nass, Klaus-Dieter Matz, M. C. De Sanctis, T. Roatsch, Christopher T. Russell, Roland Wagner, Jennifer E.C. Scully, Francesca Zambon, Scott C. Mest, David A. Williams, Ralf Jaumann, Adrian Neesemann, Federico Tosi, Carol A. Raymond, Carle M. Pieters, Debra Buczkowski, Franziska Schulzeck, Katrin Stephan, ITA, USA, and DEU

Subjects

asteroids, 010504 meteorology & atmospheric sciences, Dwarf planet, Planetengeodäsie, cryovolcanism, Astronomy and Astrophysics, Crust, Geologic map, 01 natural sciences, dwarf planet, Planetengeologie, Tectonics, Quadrangle, Impact crater, Space and Planetary Science, 0103 physical sciences, Ceres, mapping, Structural geology, Digital elevation model, 010303 astronomy & astrophysics, Geomorphology, blue material, Geology, 0105 earth and related environmental sciences

Abstract

The dwarf planet Ceres has been explored by NASA's Dawn spacecraft with the goal of characterizing its geology, mineralogy, topography, shape, and internal structure. One outcome of this exploration is the production of geologic maps, meant to unveil the geologic history of Ceres. In this paper, we present the geologic map of the Ac-6 Haulani quadrangle (Lat. 22°S-22°N, Long. 0°–72°E) based on Low Altitude Mapping Orbit (LAMO) (∼35 m/pixel) data supplemented with color and spectral data, as well as a digital terrain model from the High Altitude Mapping Orbit (HAMO) (∼135 m/pixel, vertical accuracy of about 10 m). The 34 km diameter Haulani crater is one of the youngest features on Ceres and the most prominent one in the quadrangle. Haulani was formed on a topographical transition in north–south direction and shows a complex morphology with a variety of lobate flows and tectonic features. Multiple cracks and depressions around the crater indicate the failure of subsurface material. These were likely formed by the subsidence of material due to the instability of the subsurface. The mapping of Ac-6 Haulani suggests that Ceres is built up of layers with different material properties. We propose that Ceres has a solid crust and a variable ice-rich subsurface consistent with previous and recent models of Ceres' interior.

Published

2018

20. Cryovolcanic rates on Ceres revealed by topography

Author

Michael T. Bland, Christopher T. Russell, Michael M. Sori, Shane Byrne, Ali M. Bramson, Nathaniel Stein, and Hanna G. Sizemore

Subjects

Physics, Solar System, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Astronomy and Astrophysics, Volcanism, 01 natural sciences, Silicate, Astrobiology, chemistry.chemical_compound, Volcano, chemistry, 0103 physical sciences, Geologic history, Terrestrial planet, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

Cryovolcanism, defined here as the extrusion of icy material from depth, may be an important planetary phenomenon in shaping the surfaces of many worlds in the outer Solar System and revealing their thermal histories. However, the physics, chemistry and ubiquity of this geologic process remain poorly understood, especially in comparison to the better-studied silicate volcanism on the terrestrial planets. Ceres is the only plausibly cryovolcanic world to be orbited by a spacecraft up to now, making it the best opportunity to test the importance of cryovolcanism on bodies in the outer Solar System and compare its effects to silicate volcanism on terrestrial planets. Here, we analyse images from NASA’s Dawn mission and use the finite element method to show that Ceres has experienced cryovolcanism throughout its geologic history, with an average cryomagma extrusion rate of ~10^4 m^3 yr^(−1). This result shows that volcanic phenomena are important on Ceres, but orders of magnitude less so than on the terrestrial planets.

Published

2018

21. Europan double ridge morphometry as a test of formation models

Author

Devon M. Burr and Ashley C. Dameron

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Trough (geology), Astronomy and Astrophysics, Crust, Geometry, Diapir, 010502 geochemistry & geophysics, 01 natural sciences, Angle of repose, Brittleness, Deformation mechanism, Space and Planetary Science, Ridge, Digital elevation model, Geology, 0105 earth and related environmental sciences

Abstract

Double ridges on the Jovian satellite Europa consist of two parallel ridges with a central trough. Although these features are nearly ubiquitous on Europa, their formation mechanism(s) is (are) not yet well-understood. Previous hypotheses for their formation can be divided into two groups based on 1) the expected interior slope angles and 2) the magnitude of interior/exterior slope symmetry. The published hypotheses in the first (“fracture”) group entail brittle deformation of the crust, either by diapirism, shear heating, or buckling due to compression. Because these mechanisms imply uplift of near-vertical fractures, their predicted interior slopes are steeper than the angle of repose (AOR) with shallower exterior slopes. The second (“flow”) group includes cryosedimentary and cryovolcanic processes – explosive or effusive cryovolcanism and tidal squeezing –, which are predicted to form ridge slopes at or below the AOR. Explosive cryovolcanism would form self-symmetric ridges, whereas effusive cryolavas and cryo-sediments deposited during tidal squeezing would likely not exhibit slope symmetry. To distinguish between these two groups of hypothesized formation mechanisms, we derived measurements of interior slope angle and interior/exterior slope symmetry at multiple locations on Europa through analysis of data from the Galileo Solid State Imaging (SSI) camera. Two types of data were used: i) elevation data from five stereo-pair digital elevation models (DEMs) covering four ridges (580 individual measurements), and ii) ridge shadow length measurements taken on individual images over 40 ridges (200 individual measurements). Our results shows that slopes measured on our DEMs, located in the Cilix and Banded Plains regions, typically fall below the AOR, and slope symmetry is dominant. Two different shadow measurement techniques implemented to calculate interior slopes yielded slope angles that also fall below the AOR. The shallow interior slopes derived from both techniques weigh against brittle deformation mechanisms. Although shallow slopes could result from degradation, interior/exterior ridge symmetry weighs against ridge degradation as the sole reason for shallow interior slopes. Thus, our results suggest that, for the double ridges analyzed in this work, cryovolcanic or cryosedimentary formation is more likely than brittle deformation, and of those formation mechanisms, explosive cryovolcanism is the double ridge formation mechanism best supported on the basis of interior-exterior slope symmetry.

Published

2018

22. Cryovolcanic features on Titan's surface as revealed by the Cassini Titan Radar Mapper

Author

G. Boubin, Michael Allison, Ellen R. Stofan, Charles Elachi, G. Hamilton, Steven J. Ostro, L. Roth, Randolph L. Kirk, William T. K. Johnson, Stephen D. Wall, Y. Anderson, S. Shaffer, Roberto Seu, Philip S. Callahan, Lauren Wye, R. Boehmer, Bryan Stiles, Gian Gabriele Ori, Jani Radebaugh, Karl L. Mitchell, Giovanni Picardi, Howard A. Zebker, Laurence A. Soderblom, Duane O. Muhleman, Richard West, S. Vetrella, Enrico Flamini, R. D. Lorenz, Roberto Orosei, Andrew Dominic Fortes, Jonathan I. Lunine, Yonggyu Gim, K. Kelleher, L. E. Robshaw, Catherine D. Neish, E. Reffet, Pierre Encrenaz, Scott Hensley, Flora Paganelli, Michael Janssen, Rosaly M. C. Lopes, Francesco Posa, Charles A. Wood, G. Francescetti, Jet Propulsion Laboratory, California Institute of Technology (JPL), Proxemy Research, Bowie, Lunar and Planetary Laboratory [University of Arizona] (LPL), University of Arizona, Istituto di Fisica dello Spazio Interplanetario (IFSI), National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR), US Geological Survey, Flagstaff, Wheeling Jesuit University, Environmental Sciences Department, Lancaster University, University College of London [London] (UCL), Goddard Institute for Space Studies, National Aeronautics and Space Administration New York, Observatoire de Paris, Université Paris sciences et lettres (PSL), Laboratoire d'Etude du Rayonnement et de la Matière en Astrophysique (LERMA), École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine-Centre National de la Recherche Scientifique (CNRS), Instrumentation et télédétection, Laboratoire d'Etude du Rayonnement et de la Matière en Astrophysique et Atmosphères = Laboratory for Studies of Radiation and Matter in Astrophysics and Atmospheres (LERMA), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-CY Cergy Paris Université (CY)-École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-CY Cergy Paris Université (CY), Agenzia Spaziale Italiana (ASI), Facoltá di Ingegneria, Geological and Planetary Sciences, California Institute of Technology, Pasadena, International Research School of Planetary Sciences, Dipartimento di Scienze, Università d'Annunzio, Istituto di Astrofisica Spaziale e Fisica cosmica - Roma (IASF-Roma), Istituto Nazionale di Astrofisica (INAF), Universitá La Sapienza, INFM and Dipartimento Interateneo di Fisica, and Stanford University

Subjects

Synthetic aperture radar, Solar System, geography, satellites of saturn, titan, volcanism, geography.geographical_feature_category, biology, Lava, Astronomy and Astrophysics, Venus, biology.organism_classification, Astrobiology, law.invention, symbols.namesake, Volcano, Space and Planetary Science, law, Radar imaging, symbols, Radar, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph], Titan (rocket family), Geology

Abstract

International audience; The Cassini Titan Radar Mapper obtained Synthetic Aperture Radar images of Titan's surface during four fly-bys during the mission's first year. These images show that Titan's surface is very complex geologically, showing evidence of major planetary geologic processes, including cryovolcanism. This paper discusses the variety of cryovolcanic features identified from SAR images, their possible origin, and their geologic context. The features which we identify as cryovolcanic in origin include a large (180 km diameter) volcanic construct (dome or shield), several extensive flows, and three calderas which appear to be the source of flows. The composition of the cryomagma on Titan is still unknown, but constraints on rheological properties can be estimated using flow thickness. Rheological properties of one flow were estimated and appear inconsistent with ammonia-water slurries, and possibly more consistent with ammonia-water-methanol slurries. The extent of cryovolcanism on Titan is still not known, as only a small fraction of the surface has been imaged at sufficient resolution. Energetic considerations suggest that cryovolcanism may have been a dominant process in the resurfacing of Titan.

Published

2007

23. [Untitled]

Author

S. J. Peale

Subjects

business.industry, Applied Mathematics, Astronomy, Astronomy and Astrophysics, Tidal heating, Galilean, Galilean moons, Astrobiology, Jupiter, Computational Mathematics, symbols.namesake, Space and Planetary Science, Modeling and Simulation, Saturn, Physics::Space Physics, symbols, Satellite, Astrophysics::Earth and Planetary Astrophysics, business, Enceladus, Tidal power, Physics::Atmospheric and Oceanic Physics, Mathematical Physics, Geology

Abstract

The dissipation of tidal energy causes the ongoing silicate volcanism on Jupiter's satellite, Io, and cryovolcanism almost certainly has resurfaced parts of Saturn's satellite, Enceladus, at various epochs distributed over the latter's history. The maintenance of tidal dissipation in Io and the occurrence of the same on Enceladus depends crucially on the maintenance of the respective orbital eccentricities by the existence of mean motion resonances with nearby satellites. A formation of the resonances among the Galilean satellites by differential expansion of the satellite orbits from tides raised on Jupiter by the satellites means the onset of the volcanism on Io could be relatively recent. If, on the other hand, the resonances formed by differential migration from resonant interactions of the satellites with the disk of gas and particles from which they formed, Io would have been at least intermittently volcanically active throughout its history. Either means of assembling the Galilean satellite resonances lead to the same constraint on the dissipation function of Jupiter Q J ≲ 106, where the currently high heat flux from Io seems to favor episodic heating as Io's eccentricity periodically increases and decreases. Either of the two models might account for sufficient tidal dissipation in the icy satellite Enceladus to cause at least occasional cryovolcanism over much of its history. However, both models are assumption-dependent and not secure, so uncertainty remains on how tidal dissipation resurfaced Enceladus.

Published

2003

24. Titan: An exogenic world?

Author

Robert T. Pappalardo and Jeffrey M. Moore

Subjects

geography, geography.geographical_feature_category, Landform, Fluvial, Astronomy and Astrophysics, Tidal heating, Mass wasting, Astrobiology, symbols.namesake, Impact crater, Space and Planetary Science, symbols, Aeolian processes, Atmosphere of Titan, Titan (rocket family), Geology

Abstract

All landforms on Titan that are unambiguously identifiable can be explained by exogenic processes (aeolian, fluvial, impact cratering, and mass wasting). Previous suggestions of endogenically produced cryovolcanic constructs and flows have, without exception, lacked conclusive diagnostic evidence. The modification of sparse recognizable impact craters (themselves exogenic) can be explained by aeolian and fluvial erosion. Tectonic activity could be driven by global thermal evolution or external forcing, rather than by active interior processes. A lack of cryovolcanism would be consistent with geophysical inferences of a relatively quiescent interior: incomplete differentiation, only minor tidal heating, and possibly a lack of internal convection today. Titan might be most akin to Callisto with weather: an endogenically relatively inactive world with a cool interior. We do not aim to disprove the existence of any and all endogenic activity at Titan, nor to provide definitive alternative hypotheses for all landforms, but instead to inject a necessary level of caution into the discussion. The hypothesis of Titan as a predominantly exogenic world can be tested through additional Cassini observations and analyses of putative cryovolcanic features, geophysical and thermal modeling of Titan’s interior evolution, modeling of icy satellite landscape evolution that is shaped by exogenic processes alone, and consideration of possible means for supplying Titan’s atmospheric constituents that do not rely on cryovolcanism.

Published

2011

25. Recent cryovolcanic activity at Occator crater on Ceres

Author

Carol A. Raymond, Jian-Yang Li, C. M. Pieters, H. Hiesinger, Guneshwar Thangjam, Julie C. Castillo-Rogez, Andreas Nathues, Jan Hendrik Pasckert, Nico Schmedemann, Ottaviano Ruesch, Edward A. Cloutis, L. Le Corre, Kurt Mengel, Vishnu Reddy, Michael J. Hoffmann, and David A. Williams

Subjects

Nine million, Paleontology, 010504 meteorology & atmospheric sciences, Impact crater, 0103 physical sciences, Astronomy and Astrophysics, Extrusive, Chronostratigraphy, 010303 astronomy & astrophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences, Chronology

Abstract

NASA’s Dawn mission revealed a partially differentiated Ceres that has experienced cryovolcanic activity throughout its history up to the recent past. The Occator impact crater, which formed ~22 Myr ago, displays bright deposits (faculae) across its floor whose origins are still under debate: two competing hypotheses involve eruption of brines from the crust–mantle transition boundary (remnants of an ancient ocean) or alternatively from a shallow impact melt chamber. Here we report new constraints on the history of Occator that help in testing the hypotheses of its formation. We used high-resolution images of the Dawn Framing Camera obtained close to the end of the mission. We found a long-lasting and recent period of cryovolcanic activity, which started ≤9 Myr ago and lasted for several million years. Several resurfacing events, affecting the faculae and some (dark) solidified impact melt units, are shown to have occurred millions of years after crater formation and the dissipation of the impact-generated heat. These findings are indicative of a deep-seated brine source. Extensive volatile-driven emplacement of bright material occurred in the central floor, causing its subsidence due to mass loss at depth. Finally, a thick (extrusive) dome of bright material was raised in the central depression. The derived chronostratigraphy of Occator is consistent with a recently geologically active world, where salts play a major role in preserving liquid in a heat-starved body. High-spatial-resolution images of the bright points at Occator crater on Ceres, taken during the second extended Dawn mission, allowed reconstruction of the chronology of their formation. The area experienced extensive cryovolcanism less than nine million years ago that lasted several million years, indicating recent geological activity.

Published

2020

26. Thermal convection in the crust of the dwarf planet – I. Ceres

Author

Michelangelo Formisano, Julie Castillo-Rogez, M. C. De Sanctis, Gianfranco Magni, and Costanzo Federico

Subjects

Physics, Convection, Work (thermodynamics), 010504 meteorology & atmospheric sciences, Convective heat transfer, Dwarf planet, Astronomy and Astrophysics, Crust, Geophysics, Diapir, 01 natural sciences, Bulk density, Space and Planetary Science, Asteroid, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

Ceres is the largest body in the Main Belt, and it is characterized by a large abundance of water ice in its interior. This feature is suggested by its relatively low bulk density (2162 kg m−3), while its partial differentiation into a rocky core and icy crust is suggested by several geological and geochemical features: minerals and salts produced by aqueous alteration, icy patches on the surface, and lobate morphology interpreted as surface flows. In this work, we explore how the composition can influence the characteristics of thermal convection in the crust of Ceres. Our results suggest that the onset of thermal convection is difficult and when it occurs, it is short lived, which could imply that Ceres preserved deep liquid until present, as recently suggested by the work of Castillo-Rogez et al. Moreover, cryovolcanism could be driven by diapirism (chemical convection) rather than thermal convection.

Published

2020

27. Modeling the formation of Menrva impact crater on Titan: Implications for habitability

Author

Brandon C. Johnson, Michael Malaska, Elizabeth A. Silber, E. E. Bjonnes, R. M. C. Lopes, Steve Vance, A. Solomonidou, Jason M. Soderblom, Christophe Sotin, and A. P. Crósta

Subjects

geography, geography.geographical_feature_category, Bedrock, Astronomy and Astrophysics, Context (language use), Astrobiology, Atmosphere, symbols.namesake, Impact crater, Space and Planetary Science, Hypervelocity, symbols, Erosion, Titan (rocket family), Subsurface flow, Geology

Abstract

Titan is unique in the solar system: it is an ocean world, an icy world, an organic world, and has a dense atmosphere. It is a geologically active world as well, with ongoing exogenic processes, such as rainfall, sediment transportation and deposition, erosion, and possible endogenic processes, such as tectonism and cryovolcanism. This combination of an organic and an ocean world makes Titan a prime target for astrobiological research, as biosignatures may be present in its surface, in impact melt deposits and in cryovolcanic flows, as well as in deep ice and water ocean underneath the outer ice shell. Impact craters are important sites in this context, as they may have allowed an exchange of materials between Titan's layers, in particular between the surface, composed of organic sediments over icy bedrock, and the subsurface ocean. It is also possible that impacts may have favored the advance of prebiotic chemical reactions themselves, by providing thermal energy that would allow these reactions to proceed. To investigate possible exchange pathways between the subsurface water ocean and the organic-rich surface, we modeled the formation of the largest crater on Titan, Menrva, with a diameter of ca. 425 km. The premise is that, given a large enough impact event, the resulting crater could breach into Titan's ice shell and reach the subsurface ocean, creating pathways connecting the surface and the ocean. Materials from the deep subsurface ocean, including salts and potential biosignatures of putative subsurface biota, could be transported to the surface. Likewise, atmospherically derived organic surface materials could be directly inserted into the ocean, where they could undergo aqueous hydrolysis to form potential astrobiological building blocks, such as amino acids. To study the formation of a Menrva-like impact crater, we staged numerical simulations using the iSALE-2D shock physics code. We varied assumed ice shell thickness from 50 to 125 km and assumed thermal structure over a range consistent with geophysical data. We analyze the implications and potential contributions of impact cratering as a process that can facilitate the exchange of surface organics with liquid water. Our findings indicate that melt and partial melt of ice took place in the central zone, reaching ca. 65 km depth and ca. 60 km away from the center of the structure. Furthermore, a volume of ca. 102 km3 of ocean water could be traced to depths as shallow as 10 km. These results highlight the potential for a significant exchange of materials from the surface (organics and ice) and the subsurface (water ocean), particularly in the crater's central area. Our studies suggest that large hypervelocity impacts are a viable and likely key mechanism to create pathways between the underground water ocean and Titan's organic-rich surface layer and atmosphere.

Published

2021

28. Mapping Europa's microfeatures in regional mosaics: New constraints on formation models

Author

Kelsi N. Singer, Alyssa Rhoden, J. L. Noviello, and Z. A. Torrano

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Feature (archaeology), Liquid water, Numerical modeling, Astronomy and Astrophysics, 01 natural sciences, Data set, Sill, Space and Planetary Science, 0103 physical sciences, Scale (map), 010303 astronomy & astrophysics, Cartography, Geology, 0105 earth and related environmental sciences

Abstract

Europa is an unusual world, and its surface features provide clues as to how it has evolved. We mapped, characterized, and analyzed small (≤100 km2 in area) endogenic features on Europa's surface in order to identify patterns among and within different types of features and provide observational tests for formation models. To create a fully digitized and validated data set of these microfeatures, we merged data sets obtained by previous mapping studies that focused on small chaos, domes, pits, spots, and hybrid features in moderate resolution (~230 m/pix) images of Europa, including the four main regional map areas. We expanded upon the definition of a recently-identified feature definition type, here called hybrids, and suggest more quantitative metrics for describing pits, spots, domes, and microchaos. Across all four regions mapped, we find that microchaos are the most numerous, followed by pits and domes, respectively. Spots are the least common features, and the smallest, which might indicate an observational bias, as they may contain disruptions smaller than what is visible at this scale. Microchaos features are, on average, larger and darker than all other microfeature types. We compare our observations to the findings and predictions of previous numerical modeling studies, and suggest that the observations are most consistent with cryovolcanism and liquid water sill models. While no one model is able to explain all the observations, there are elements of each that should be considered in future modeling studies.

Published

2019

29. A corridor of exposed ice-rich bedrock across Titan’s tropical region

Author

Nicholas J. Montiel, Paulo Penteado, Rosaly M. C. Lopes, Ashley Schoenfeld, Catherine D. Neish, Caitlin A. Griffith, G. Mitri, and Jake D. Turner

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Feature (archaeology), Bedrock, Astronomy and Astrophysics, Terrain, 01 natural sciences, Astrobiology, Latitude, Atmosphere, symbols.namesake, Impact crater, 0103 physical sciences, symbols, Erosion, Titan (rocket family), 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Global maps of Titan show great diversity in terrain types, but their associations with specific compositions on a large scale are obscured by Titan’s thick atmosphere, which shrouds the weak spectral features. Here we develop a principal component analysis (PCA) that enables the identification of subtle spectral features. The PCA was applied to over 13,000 Cassini/VIMS spectra that cover half of Titan’s globe, focused on tropical latitudes. Our analysis detected an ice-rich linear feature of bedrock, which extends a length equivalent to 40 per cent of Titan’s circumference. This corridor is puzzling because it does not correlate with topography or measurements of the subsurface. Ice-rich terrains in other areas of Titan occur only in local regions excavated by craters or exposed by erosion, suggesting that cryovolcanism, if active, is currently not widespread. We also find evidence for a diversity of organic sediments, formed by the photolysis of Titan’s past atmospheres, which remain to be investigated, perhaps using a similar approach. A principal component analysis of Cassini’s infrared spectral maps of Titan reveals the main features of Titan’s equatorial surface, effectively removing the obscuring atmospheric effects. A 6,300-kilometre-long strip of exposed icy bedrock—uncorrelated with topography or measurements of the subsurface—is visible, surrounded by organic deposits.

Published

2019

30. A Possible Brine Reservoir Beneath Occator Crater: Thermal and Compositional Evolution and Formation of the Cerealia Dome and Vinalia Faculae

Author

Jennifer E.C. Scully, P. M. Schenk, Carol A. Raymond, Hanna G. Sizemore, Lynnae C. Quick, Ottaviano Ruesch, Debra Buczkowski, Mark V. Sykes, and Julie Castillo-Rogez

Subjects

Explosive eruption, 010504 meteorology & atmospheric sciences, Lava, Astronomy and Astrophysics, Crust, 01 natural sciences, Chloride, Brine, Impact crater, Space and Planetary Science, 0103 physical sciences, Thermal, medicine, Petrology, 010303 astronomy & astrophysics, Bouguer anomaly, Geology, 0105 earth and related environmental sciences, medicine.drug

Abstract

The Dawn spacecraft has imaged several putative cryovolcanic features on Ceres, and several lines of evidence point to past cryovolcanic activity at Occator crater. It is therefore possible that cryovolcanism played a key role in delivering sodium carbonate- and chloride-enriched brines to Ceres’ surface in recent geological times. The detection of a 200 km×200 km negative Bouguer anomaly beneath Occator suggests the presence of a low-density region beneath the crater. If this region is a residual, partially crystallized, cryomagma chamber, excess pressures caused by its gradual freezing, or stresses produced by the Occator-forming impact, could have facilitated the delivery of cryolavas to the surface in the geologically recent past. Here, the progressive solidification of a cryomagma chamber beneath Occator and implications for the delivery of cryolavas to the surface has been explored. Models for the behavior of cryolavas at Ceres’ surface, and for the formation of the Cerealia Dome and Vinalia Faculae, are also presented. Minimal crystallization of a subsurface fluid reservoir located at the crust-mantle boundary could have driven cryolavas enriched in chloride salts and NH3 to Ceres’ surface. However, cryolavas enriched in sodium carbonates would have had to have existed at shallower levels in the crust in order to be delivered to the surface via pressure-driven ascent. Depending on the size of the reservoir, cryolavas could have been driven to Ceres’ surface for tens to hundreds of millions of years after cooling of the cryomagma chamber commenced. The mineralogy at Occator is suggestive of subsurface cryomagma reservoirs enriched in sodium carbonate and chloride salts. Aqueous solutions enriched in chloride salts and/or ammonia would have arrived at the surface at warm enough temperatures to erupt if transported in propagating fractures that traveled at least 10−5 m/s. Additionally, if the Cerealia Dome was formed from viscous cryolava extrusions, bulk kinematic lava viscosities may have been between 106–108 m2/s at the onset of relaxation. Plausible relaxation times to form the dome, which are linked to bulk cryolava rheology, are found to have ranged from 2.5 to 273 days. Moreover, the low volatile content necessary to drive explosive eruptions on Ceres supports the possibility that Cerealia and Vinalia Faculae were emplaced as a consequence of ballistic eruptions. The enigmatic geology of Occator crater is consistent with a diversity of exchange processes operating on Ceres in the geologically recent past. Further, the processes that have occurred at Occator could shed light on the changing geology associated with a relic ocean world. Future studies of Occator and Ceres should be undertaken with these results in mind.

Published

2019

31. Viscous relaxation as a prerequisite for tectonic resurfacing on Ganymede: Insights from numerical models of lithospheric extension

Author

William B. McKinnon and Michael T. Bland

Subjects

010504 meteorology & atmospheric sciences, Deformation (mechanics), Astronomy and Astrophysics, Terrain, Geophysics, 01 natural sciences, Tectonics, Extension (metaphysics), Amplitude, Impact crater, Space and Planetary Science, Lithosphere, 0103 physical sciences, Relaxation (physics), 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Ganymede’s bright terrain formed during a near-global resurfacing event (or events) that produced both heavily tectonized and relatively smooth terrains. The mechanism(s) by which resurfacing occurred on Ganymede (e.g., cryovolcanic or tectonic), and the relationship between the older, dark and the younger, bright terrain are fundamental to understanding the geological evolution of the satellite. Using a two-dimensional numerical model of lithospheric extension that has previously been used to successfully simulate surface deformation consistent with grooved terrain morphologies, we investigate whether large-amplitude preexisting topography can be resurfaced (erased) by extension (i.e., tectonic resurfacing). Using synthetically produced initial topography, we show that when the total relief of the initial topography is larger than 25–50 m, periodic groove-like structures fail to form. Instead, extension is localized in a few individual, isolated troughs. These results pose a challenge to the tectonic resurfacing hypothesis. We further investigate the effects of preexisting topography by performing suites of simulations initialized with topography derived from digital terrain models of Ganymede’s surface. These include dark terrain, fresh (relatively deep) impact craters, smooth bright terrain, and a viscously relaxed impact crater. The simulations using dark terrain and fresh impact craters are consistent with our simulations using synthetic topography: periodic groove-like deformation fails to form. In contrast, when simulations were initialized with bright smooth terrain topography, groove-like deformation results from a wide variety of heat flow and surface temperature conditions. Similarly, when a viscously relaxed impact crater was used, groove-like structures were able to form during extension. These results suggest that tectonic resurfacing may require that the amplitude of the initial topography be reduced before extension begins. We emphasize that viscous relaxation may be the key to enabling tectonic resurfacing, as the heat fluxes associated with groove terrain formation are also capable of reducing crater topography through viscous relaxation. For long-wavelength topography (large craters) viscous relaxation is unavoidable. We propose that the resurfacing of Ganymede occurred through a combination of viscous relaxation, tectonic resurfacing, cryovolcanism and, at least in a few cases, band formation. Variations in heat flow and strain magnitudes across Ganymede likely produced the complex variety of terrain types currently observed.

Published

2018

32. Pluto: Pits and mantles on uplands north and east of Sputnik Planitia

Author

Bernard Schmitt, Orkan M. Umurhan, John R. Spencer, Jeffrey M. Moore, S. Philippe, Oliver L. White, Kimberly Ennico, Alan D. Howard, Catherine B. Olkin, Paul M. Schenk, Harold A. Weaver, S. Alan Stern, Leslie A. Young, William B. McKinnon, Ross A. Beyer, and William M. Grundy

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Landform, Geochemistry, Astronomy and Astrophysics, Terrain, 01 natural sciences, Mantle (geology), Pluto, Lineation, Tectonics, Reticulate, Space and Planetary Science, 0103 physical sciences, human activities, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

The highlands region north and east of Sputnik Planitia can be subdivided into seven terrain types based on their physiographic expression. The northern rough uplands are characterized by jagged uplands and broad troughs, and it may contain a deeply-eroded ancient mantle. Dissected terrain has been interpreted to have been eroded by paleo-glaciation. The smooth uplands and pits terrain contains broad, rolling uplands surrounding complexes of pits, some of which contain smooth floors. The uplands are mantled by smooth-surfaced deposits possibly derived from adjacent pits through low-power explosive cryovolcanism or through slow vapor condensation. The eroded smooth uplands appear to have originally been smooth uplands and pits terrain modified by small-scale sublimation pitting. The bright pitted uplands features intricate texturing by reticulate ridges that may have originated by sublimation erosion, volatile condensation, or both. The bladed terrain is characterized by parallel ridges oriented north–south and is discussed in a separate paper. The dark uplands are mantled with reddish deposits that may be atmospherically deposited tholins. Their presence has affected long-term landform evolution. Widespread pit complexes occur on most of the terrain units. Most appear to be associated with tectonic lineations. Some pits are floored by broad expanses of ices, whereas most feature deep, conical depressions. A few pit complexes are enclosed by elevated rims of uncertain origin.

Published

2017

33. Measuring temperature and ammonia hydrate ice on Charon in 2015 from Keck/OSIRIS spectra

Author

Marc W. Buie, Leslie A. Young, Bryan J. Holler, James E. Lyke, Eliot F. Young, Henry G. Roe, and William M. Grundy

Subjects

Earth and Planetary Astrophysics (astro-ph.EP), Materials science, 010504 meteorology & atmospheric sciences, FOS: Physical sciences, Astronomy, Astronomy and Astrophysics, Astrophysics, 01 natural sciences, Temperature measurement, Spectral line, Mantle (geology), Amorphous solid, Pluto, Full width at half maximum, Space and Planetary Science, 0103 physical sciences, Thermal, Hydrate, 010303 astronomy & astrophysics, Astrophysics - Earth and Planetary Astrophysics, 0105 earth and related environmental sciences

Abstract

In this work we investigated the longitudinal (zonal) variability of H$_2$O and ammonia (NH$_3$) hydrate ices on the surface of Charon through analysis of the 1.65 $\mu$m and 2.21 $\mu$m absorption features, respectively. Near-infrared spectra presented here were obtained between 2015-07-14 and 2015-08-30 UT with the OSIRIS integral field spectrograph on Keck I. Spectra centered on six different sub-observer longitudes were obtained through the Hbb (1.473-1.803 $\mu$m) and Kbb (1.965-2.381 $\mu$m) filters. Gaussian functions were fit to the aforementioned bands to obtain information on band center, band depth, full width at half maximum, and band area. The shift in the band center of the temperature-dependent 1.65 $\mu$m feature was used to calculate the H$_2$O ice temperature. The mean temperature of the ice on the observable portion of Charon's surface is 45$\pm$14 K and we report no statistically significant variations in temperature across the surface. We hypothesize that the crystalline and amorphous phases of water ice reached equilibrium over 3.5 Gyr ago, with thermal recrystallization balancing the effects of irradiation amorphization. We do not believe that cryovolcanism is necessary to explain the presence of crystalline water ice on the surface of Charon. Absorption from ammonia species is detected between 12$^{\circ}$ and 290$^{\circ}$, in agreement with results from New Horizons. Ongoing diffusion of ammonia through the rocky mantle and upper layer of water ice is one possible mechanism for maintaining its presence in Charon's surface ice. Reduced Charon spectra corrected for telluric and solar absorption are available as supplementary online material., Comment: 31 pages, 10 figures, 3 tables

Published

2017

34. Regional study of Europa’s photometry

Author

Ines Belgacem, Grégory Jonniaux, Frédéric Schmidt, Géosciences Paris Sud (GEOPS), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Airbus Defence and Space [Toulouse], Géosciences Paris Saclay (GEOPS), Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Airbus Defence & Space, Toulouse, France and the French National re-search Agency (ANR) as part of the « Investissement d’Avenir » program, through the 'IDI 2016' project funded by the IDEX, and ANR-11-IDEX-0003,IPS,Idex Paris-Saclay(2011)

Subjects

010504 meteorology & atmospheric sciences, photometry, Forward scatter, [PHYS.ASTR.EP]Physics [physics]/Astrophysics [astro-ph]/Earth and Planetary Astrophysics [astro-ph.EP], satellite, FOS: Physical sciences, Astrophysics, Bayesian inversion, 01 natural sciences, Space weathering, Photometry (optics), Atmospheric radiative transfer codes, [SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, 0103 physical sciences, Radiative transfer, surface, Imaging science, 010303 astronomy & astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), 0105 earth and related environmental sciences, Earth and Planetary Astrophysics (astro-ph.EP), Pixel, geophysics, Astronomy and Astrophysics, BRDF, 13. Climate action, Space and Planetary Science, radiative transfer, [SDU]Sciences of the Universe [physics], Physics - Data Analysis, Statistics and Probability, Bidirectional reflectance distribution function, Astrophysics::Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Europa, Geology, Data Analysis, Statistics and Probability (physics.data-an), Hapke model, Astrophysics - Earth and Planetary Astrophysics

Abstract

The surface of Europa is geologically young and shows signs of current activity. Studying it from a photometric point of view gives us insight on its physical state. We used a collection of 57 images from Voyager's Imaging Science System and New Horizons' LOng Range Reconnaissance Imager for which we corrected the geometric metadata and projected every pixel to compute photometric information (reflectance and geometry of observation). We studied 20 areas scattered across the surface of Europa and estimated their photometric behavior using the Hapke radiative transfer model and a Bayesian framework in order to estimate their microphysical state. We have found that most of them were consistent with the bright backscattering behavior of Europa, already observed at a global scale, indicating the presence of grains maturated by space weathering. However, we have identified very bright areas showing a narrow forward scattering possibly indicating the presence of fresh deposits that could be attributed to recent cryovolcanism or jets. Overall, we showed that the photometry of Europa's surface is more diverse than previously thought and so is its microphysical state., Comment: 46 pages, 17 figures, 3 tables

Published

2019

35. Titan's ionospheric chemistry, fullerenes, oxygen, galactic cosmic rays and the formation of exobiological molecules on and within its surfaces and lakes

Author

Ashraf Ali, Edward C. Sittler, John F. Cooper, and Steven J. Sturner

Subjects

chemistry.chemical_classification, Fullerene, 010504 meteorology & atmospheric sciences, Chemistry, chemistry.chemical_element, Astronomy and Astrophysics, Tholin, Cosmic ray, Photochemistry, Mass spectrometry, 01 natural sciences, Nitrogen, Ion, symbols.namesake, Hydrocarbon, Space and Planetary Science, 0103 physical sciences, symbols, Titan (rocket family), 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

We discuss the formation of aerosols within Titan's thermosphere-ionosphere and the different chemical pathways. Negative ion measurements by the Cassini Plasma Spectrometer (CAPS) Electron Spectrometer (ELS) give evidence for formation of unsaturated anion carbon chains, while positive ion measurements of the Cassini Ion Neutral Mass Spectrometer (INMS) indicate formation of more aromatic cation hydrocarbons. There is presently no direct observational evidence for large neutral molecule growth in Titan's thermosphere-ionosphere. The hydrocarbon cations are expected to form Polycyclic Aromatic Hydrocarbons (PAH), those with the addition of nitrogen being called PAHNs. We theorize anion carbon chains can eventually become long enough to fold into fullerene C60,70 carbon shells, of various charge states. Based on laboratory data the fullerenes can trap incoming O+ magnetospheric ions that have relatively high energy collisions with the fullerenes and, once trapped, protect the oxygen atom from Titan's reducing thermosphere-ionosphere. The fullerenes can form into larger onion fullerenes and condense into larger embryo aerosols (i.e., m/q > 10,000 amu/q anions as observed by CAPS/ELS) eventually falling onto Titan's surface and precipitating to the bottom of its hydrocarbon lakes. Molecule production composed of H, C, N is known to occur in Titan's atmosphere with energy input from the magnetosphere, solar UV, and deep-penetrating irradiation from galactic cosmic rays (GCR). Space radiation effects by GCR irradiation of Titan's surface and lakes can lead to the manufacture of exobiological molecules with oxygen as the new ingredient. We have developed a model of galactic cosmic ray irradiation of Titan's atmosphere, surface, subsurface and bottoms of Titan lakes. GCR would provide further energy for processing of the aerosols into more complex organic forms such as tholins and precursor molecules for amino acids. A second process called hydrolysis then converts the precursor molecules into amino acids. Hydrolysis is provided via meteor impacts with size >10 km and cryovolcanism both which can produce liquid water on Titan's surface for episodic periods > several 100 to 1000 years. Our model shows that GCR secondary particles can penetrate ~ 100 m below the ice surface (including the bottom of Titan's less dense hydrocarbon lakes ~ 150 m depths) and produce chemically significant dosages over very long timescales ~ 450 Myrs. The GCR model is combined with laboratory data from experiments in which dry methyl ices were irradiated to doses producing prebiotic amino acids such as glycine. The model calculations show glycine can form to ~ 2.5 ppb levels near the surface after ~ 450 Myrs of GCR proton irradiation and potentially to 5 ppb if heavy-ion GCRs up through Fe are included. If such molecules were detected, this would not only confirm this model but indicate that life forms different from ours may not be required.

Published

2020

36. Mineralogical Analysis of Quadrangle Ac-H-10 Rongo on the Dwarf Planet Ceres

Author

ZAMBON, Francesca, CARROZZO, FILIPPO GIACOMO, TOSI, Federico, CIARNIELLO, Mauro, Combe, J. Ph., FRIGERI, ALESSANDRO, DE SANCTIS, MARIA CRISTINA, Thangjam, G., Nathues, A., Hoffmann, M., LONGOBARDO, ANDREA, Stephan, K., RAPONI, Andrea, Ammannito, E., Krohn, K., McFadden, L. A., PALOMBA, Ernesto, Raymond, C. A., Russell, C. T., Dawn Science Team, ITA, USA, and DEU

Subjects

010504 meteorology & atmospheric sciences, Dwarf planet, Geochemistry, Astronomy and Astrophysics, Crust, 01 natural sciences, Hydrothermal circulation, Dawn, chemistry.chemical_compound, Quadrangle, Impact crater, chemistry, Space and Planetary Science, Homogeneous, 0103 physical sciences, Carbonate, Ceres, Ejecta, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Quadrangle Ac-H-10 'Rongo' (Lat 22°S to 22°N, Lon 288°-360°E) shows a fairly homogeneous topography, with the presence of notable elevations such as Ahuna Mons, Liberalia Mons, and part of Samhain and Uhola Catenae. The deepest areas correspond to the Rongo crater region, the areas between Samhain and Uhola catenae, and the region of the quadrangle south of Ahuna Mons. A substantial variability in the 2.7-μm band depth distribution is observed across the Rongo quadrangle, indicating an east-west gradient in the abundance of Mg-phyllosilicates. The NH4-phyllosilicates distribution appears quite homogeneous, except some localized regions, such as crater Haulani's ejecta, the flanks of Ahuna Mons, and crater Begbalel. The two band depths at 2.7 and 3.1 μm display an overall low correlation, suggesting a variable degree of mixing between Mg-phyllosilicates and NH4-phyllosilicates. At the local scale, mineralogical phases other than phyllosilicates are observed. Quadrangle Rongo includes sodium carbonate-rich regions, such as the flanks of Ahuna Mons, the ejecta of Xevioso crater located in the southern edge of Liberalia Mons, and crater Begbalel, which often display a reduction in both the 2.7- and 3.1-μm band depths, associated with an increased band depth at ∼4 μm, related to the presence of Na-rich carbonate phases. This suggests recent hydrothermal activity in this area, due to several episodes of cryovolcanism, or impacts that unveiled a peculiar composition in the shallow subsurface. Alternatively, the crust in this region might show a variable degree of compactness, such that the formation of Na-carbonates is favored only in specific locations (De Sanctis et al., 2016; Ruesch et al., 2016; Zambon et al., 2017). From a geological standpoint, quadrangle Ac-H-10 Rongo shows a correlation between its two main geologic units (Platz et al., 2017) and the distribution of Mg-phyllosilicates, suggesting a link between geology and mineralogy in this area.

Published

2019

37. Dione’s resurfacing history as determined from a global impact crater database

Author

Michelle R. Kirchoff and Paul M. Schenk

Subjects

Database, Impact crater, Space and Planetary Science, Saturn, Astronomy and Astrophysics, Terrain, computer.software_genre, Variation (astronomy), computer, Geology

Abstract

Saturn’s moon Dione has an interesting and unique resurfacing history recorded by the impact craters on its surface. In order to further resolve this history, we compile a crater database that is nearly global for diameters (D) equal to and larger than 4 km using standard techniques and Cassini Imaging Science Subsystem images. From this database, spatial crater density maps for different diameter ranges are generated. These maps, along with the observed surface morphology, have been used to define seven terrain units for Dione, including refinement of the smooth and “wispy” (or faulted) units from Voyager observations. Analysis of the terrains’ crater size–frequency distributions (SFDs) indicates that: (1) removal of D ≈ 4–50 km craters in the “wispy” terrain was most likely by the formation of D ≳ 50 km craters, not faulting, and likely occurred over a couple billion of years; (2) resurfacing of the smooth plains was most likely by cryovolcanism at ∼2 Ga; (3) most of Dione’s largest craters (D ⩾ 100 km), including Evander (D = 350 km), may have formed quite recently (

Published

2015

38. Geology before Pluto: Pre-encounter considerations

Author

William B. McKinnon, S. Alan Stern, Dennis C. Reuter, Alan D. Howard, Leslie A. Young, John R. Spencer, Catherine B. Olkin, Ross A. Beyer, Bonnie J. Buratti, William M. Grundy, Paul M. Schenk, Harold A. Weaver, Harold J. Reitsema, Richard P. Binzel, Robert T. Pappalardo, Jeffrey M. Moore, Veronica J. Bray, Edward B. Bierhaus, and Ryan C. Ewing

Subjects

Pluto, Tectonics, New horizons, Geological analysis, Planetary surface, Impact crater, Space and Planetary Science, Astronomy and Astrophysics, Planetary Evolution, Planetary geology, Geology, Astrobiology

Abstract

The cameras of New Horizons will provide robust data sets that should be imminently amenable to geological analysis of the Pluto system’s landscapes. In this paper, we begin with a brief discussion of the planned observations by the New Horizons cameras that will bear most directly on geological interpretability. Then we broadly review the major geological processes that could potentially operate on the surfaces of Pluto and its major moon Charon. We first survey exogenic processes (i.e. those for which energy for surface modification is supplied externally to the planetary surface): impact cratering, sedimentary processes (including volatile migration), and the work of wind. We conclude with an assessment of the prospects for endogenic activity in the form of tectonics and cryovolcanism.

Published

2015

39. Conditions for liquid or icy core existence in KBO objects: Numerical simulations for Orcus and Quaoar

Author

Roberto Orosei, O. B. Shchuko, D. V. Kartashov, and S. D. Shchuko

Subjects

Core (optical fiber), Physics, Phase transition, Accretion rate, Radiogenic nuclide, Space and Planetary Science, Heat generation, Dust particles, Thermal, Astronomy and Astrophysics, Intensity (heat transfer), Astrobiology

Abstract

In this article, we present a model describing the thermal evolution and structure of Kuiper belt objects (KBO) as a function of the intensity of radiogenic heat sources, mean density and the object׳s formation time. We have studied numerically the dependence of the interior composition and structure of a forming body on the accretion rate and radionuclide content in the dust particles, as well as the impact of the radiogenic heat generation rate on the water phase transition dynamics. The model is applied to predict the present internal structure of Plutino (90482) Orcus and KBO (50000) Quaoar with special emphasis on the possibility of cryovolcanism.

Published

2014

40. Ahuna Mons lonely no more

Author

Lynnae C. Quick

Subjects

geography, Solar System, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Volcano, 0103 physical sciences, Dwarf planet, Astronomy and Astrophysics, 010303 astronomy & astrophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences, Astrobiology

Abstract

Volcanic domes are common in our Solar System but so far only one has been identified on dwarf planet Ceres. New research suggests that numerous volcanic domes may have formed throughout Ceres’s history, indicating that cryovolcanism may have once been more common on the dwarf planet.

Published

2018

41. Photometric Measurements of H2O Ice Crystallinity on Trans-Neptunian Objects

Author

Yoichi Itoh, Reiko Furusho, Yumiko Oasa, Tsuyoshi Terai, and Jun-ichi Watanabe

Subjects

Physics, Earth and Planetary Astrophysics (astro-ph.EP), 010504 meteorology & atmospheric sciences, Haumea, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, 01 natural sciences, Grain size, Amorphous solid, law.invention, Crystallinity, Space and Planetary Science, law, Phase (matter), 0103 physical sciences, Trans-Neptunian object, Crystallization, Absorption (electromagnetic radiation), 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Astrophysics - Earth and Planetary Astrophysics

Abstract

We present a measurement of H2O ice crystallinity on the surface of trans-neptunian objects (TNOs) with near-infrared narrow-band imaging. The newly developed photometric technique allows us to efficiently determine the strength of an 1.65-um absorption feature in crystalline H2O ice. Our data for three large objects, Haumea, Quaoar, and Orcus, which are known to contain crystalline H2O ice on the surfaces, show a reasonable result with high fractions of the crystalline phase. It can also be pointed out that if the H2O-ice grain size is larger than ~20 um, the crystallinities of these objects are obviously below 1.0, which suggest the presence of the amorphous phase. Especially, Orcus exhibits a high abundance of amorphous H2O ice compared to Haumea and Quaoar, possibly indicating a correlation between bulk density of the bodies and surface crystallization degree. We also found the presence of crystalline H2O ice on Typhon and 2008 AP129, both of which are smaller than the minimum size limit for inducing cryovolcanism as well as a transition from amorphous to crystalline through the thermal evolution due to the decay of long-lived isotopes., 31 pages, 7 figures, 6 tables, accepted for publication in ApJ

Published

2016

42. Geomorphologic mapping of the Menrva region of Titan using Cassini RADAR data

Author

Rosaly M. C. Lopes, Jani Radebaugh, David A. Williams, and Ellen R. Stofan

Subjects

Astronomy and Astrophysics, Geologic map, Fault scarp, law.invention, Tectonics, symbols.namesake, Impact crater, Space and Planetary Science, law, Radar imaging, symbols, Radar, Titan (rocket family), Ejecta, Geomorphology, Geology, Remote sensing

Abstract

We made a detailed geomorphologic map of the Menrva region of Titan, using Cassini RADAR data as our map base. Using similar techniques and approaches that were applied to mapping Magellan radar images of Venus, and earlier, more generalized Titan maps, we were able to define and characterize 10 radar morphologic units, along with inferred dunes and fluvial channels, from the RADAR data. Structural features, such as scarps, ridges, and lineaments were also identified. Using principles of superposition, cross-cutting, and embayment relations we created a sequence of map units for this region. We interpret Menrva to be a 440 km wide degraded impact basin, in agreement with earlier studies by Elachi et al. (Elachi, C. et al. [2006]. Nature 441, 709–713) and Wood et al. (Wood, C.A., Lorenz, R., Kirk, R., Lopes, R., Mitchell, K., Stofan, E., and the Cassini RADAR Team [2010]. Icarus 206, 334–344), and identify it as the oldest feature in the map region. Exogenic processes including hydrocarbon fluid channelization forming the Elivagar Flumina channel network and dune fields resulting from aeolian activity are the current geologic processes dominating our map area, and these processes have contributed to the erosion of the crater’s ejecta field. There is evidence of multiple episodes of channel formation, erosion and burial by aeolian deposits, as observed elsewhere on Titan by e.g., Barnes et al. (Barnes, J.W. et al. [2005]. Icarus 195, 400–414). Channel outflow regions have morphologies suggestive of streams formed by flash floods, and dune fields are small and restricted rather than forming large dune seas, consistent with a desert-like environment for this region with low supply of hydrocarbon particles, also consistent with other studies by e.g., Lorenz et al. (Lorenz, R.D. et al. [2008a]. Planet. Space Sci. 56, 1132–1144). There is no evidence of cryovolcanism or non-impact-related tectonic activity in the Menrva region, although this region is too small to infer anything about the roles of these processes elsewhere on Titan. This work suggests detailed geomorphologic mapping can confidently be applied to Cassini RADAR data, and we suggest that more extensive mapping should be done using RADAR, ISS, and VIMS data geographically distributed across Titan to assess its usefulness for a future combined RADAR–ISS–VIMS-based global geologic map.

Published

2011

43. The surface of (136108) Haumea (2003 EL61), the largest carbon-depleted object in the trans-Neptunian belt

Author

Rosario Brunetto, Noemi Pinilla-Alonso, Ted L. Roush, Javier Licandro, Ricardo Gil-Hutton, and Giovanni Strazzulla

Subjects

Rotation period, Orbital elements, Physics, Solar System, education.field_of_study, Scattering, Haumea, Population, Astronomy and Astrophysics, Astrophysics, Jupiter, Space and Planetary Science, Spectral slope, education

Abstract

2003 EL61 is the largest member of a group of TNOs with similar orbits and 'unique' spectra (neutral slope in the visible and the deepest water ice absorption bands ever observed in the TNb). Studying the composition of the surface of 2003 EL61 provides useful constrains on the origin of this particular group of TNOs and on the outer Solar system's history. We present visible and near-infrared spectra of 2003 EL61 obtained with the 4.2m WHT and the 3.6m TNG at the Roque de los Muchachos Observatory (Canary Islands, Spain). Near infrared spectra were obtained at different rotational phases covering almost one complete rotational period. Spectra are fitted using Hapke scattering models and constraints on the surface composition are derived. No significant variations in the spectral slope and in the depth of the water ice absorption bands at different rotational phases are evident, suggesting that the surface of 2003 EL61 is homogeneous. The scattering models show that a 1:1 intimate mixture of crystalline and amorphous water ice is the most probable composition for the surface of this TNO, and constrain the presence of other minor constituents to a maximum of 8% The derived composition suggests that: a) cryovolcanism is unlikely to be the main resurfacing process responsible for the high presence of water ice on the surface of these bodies; b) the surface is older than 10^8 yr. Any catastrophic event, like the collision suggested to be the origin of this population, had to happen at least 10^8 yr ago; c) the surface of 2003 EL61 is depleted of carbon chains. According to the orbital parameters of this population, this makes it a possible source of carbon-depleted Jupiter family comets.

Published

2009

44. Titan's Tropical Storms in an Evolving Atmosphere

Author

Furqan Fazal, Sridharan Tirupati Kumara, Christopher McKay, and Francesca Ferri

Subjects

Physics, Convection, Fluvial, Tropics, Astronomy and Astrophysics, Atmospheric sciences, Troposphere, symbols.namesake, Altitude, Space and Planetary Science, Convective storm detection, symbols, Tropical cyclone, Titan (rocket family)

Abstract

The Huygens probe landed in a damp lake bed fed by fluvial channels, indicative of past rainfall. Such washes, interspersed with vast dunes, are typical of Titan's tropical landscape. Yet, Cassini-Huygens measurements reveal a highly stable tropical atmosphere devoid of deep convective storms, and the formation of washes in dune fields is not understood. Here we examine the effects of seasonal variations in humidity, surface heating, and dynamical forcing on the stability of Titan's troposphere. We find that during the probe landing, the middle troposphere was weakly unstable to convection, consistent with the tenuous cloud detected at 21 km. Yet the tropical atmosphere, at any season, is too stable to produce deep convective storms. Convection in the tropics remains weak and confined to altitudes below ~30 km, unless the humidity is increased below 9 km altitude. Solar heating is insufficient to significantly humidify the tropical atmosphere. The large polar lakes are seasonably stable, and the methane column abundance measured by Huygens typical of the tropical atmosphere. Our study indicates the presence of distinct polar and equatorial climates. It also suggests that fluvial features in the tropics do not result from recent seasonal rainstorms, and thereby supports other origins such as geological seepage, cryovolcanism, or a wetter climate in the past.

Published

2008

45. The long-term stability of a possible aqueous ammonium sulfate ocean inside Titan

Author

Daniel Feltham, Peter Grindrod, Lidunka Vočadlo, Francis Nimmo, John P. Brodholt, and Andrew Dominic Fortes

Subjects

Convection, Ammonium sulfate, Underplating, Methane clathrate, Mineralogy, Astronomy and Astrophysics, Crust, Methane, Astrobiology, chemistry.chemical_compound, symbols.namesake, chemistry, Heat flux, Space and Planetary Science, symbols, Titan (rocket family), Geology

Abstract

We model the thermal evolution of a subsurface ocean of aqueous ammonium sulfate inside Titan using a parameterized convection scheme. The cooling and crystallization of such an ocean depends on its heat flux balance, and is governed by the pressure-dependent melting temperatures at the top and bottom of the ocean. Using recent observations and previous experimental data, we present a nominal model which predicts the thickness of the ocean throughout the evolution of Titan; after 4.5 Ga we expect an aqueous ammonium sulfate ocean 56 km thick, overlain by a thick (176 km) heterogeneous crust of methane clathrate, ice I and ammonium sulfate. Underplating of the crust by ice I will give rise to compositional diapirs that are capable of rising through the crust and providing a mechanism for cryovolcanism at the surface. We have conducted a parameter space survey to account for possible variations in the nominal model, and find that for a wide range of plausible conditions, an ocean of aqueous ammonium sulfate can survive to the present day, which is consistent with the recent observations of Titan's spin state from Cassini radar data [Lorenz, R.D., Stiles, B.W., Kirk, R.L., Allison, M.D., del Marmo, P.P., Iess, L., Lunine, J.I., Ostro, S.J., Hensley, S., 2008. Science 319, 1649–1651].

Published

2008

46. Resurfacing of Titan by ammonia-water cryomagma

Author

Jonathan I. Lunine, Giuseppe Mitri, Adam P. Showman, and Rosaly M. C. Lopes

Subjects

Convection, Astronomy and Astrophysics, Volcanism, Astrobiology, Latitude, Ammonia, chemistry.chemical_compound, symbols.namesake, chemistry, Neutral buoyancy, Space and Planetary Science, symbols, Formation and evolution of the Solar System, Titan (rocket family), Geology, Pressure gradient

Abstract

The Cassini Titan Radar Mapper observed on Titan several large features interpreted as cryovolcanic during the October 26, 2004 pass at high northern latitudes [Lopes, R.M.C., and 43 colleagues, 2007. Icarus 186, 395–412]. To date, models of ammonia-water resurfacing have not been tied to specific events or evolutionary stages of Titan. We propose a model of cryovolcanism that involves cracking at the base of the ice shell and formation of ammonia-water pockets in the ice. As these ammonia-water pockets undergo partial freezing in the cold ice shell, the ammonia concentration in the pockets increases, decreasing the negative buoyancy of the ammonia–water mixture. If the ice shell is contaminated by silicates delivered in impacts, the liquid–solid density difference would be even less. While the liquid cannot easily become buoyant relative to the surrounding ice, these concentrated ammonia-water pockets are sufficiently close to the neutral buoyancy point that large-scale tectonic stress patterns (tides, non-synchronous rotation, satellite volume changes, solid state convection, or subsurface pressure gradients associated with topography) would enable the ammonia to erupt effusively onto the surface. Rather than suggesting steady-state volcanism over the history of the Solar System, we favor a scenario where the cryovolcanic features could have been associated with episodic (potentially late) geological activity.

Published

2008

47. Titan's methane cycle

Author

Hasso B. Niemann, E. Y. Adams, Francesca Ferri, Tobias Owen, Sushil K. Atreya, Marcello Fulchignoni, Jaime E. Demick-Montelara, Eric Wilson, Department of Atmospheric, Oceanic and Space Sciences, University of Michigan, Goddard Space Flight Center, NASA, Astrophysics Science Division, Institute for Astronomy, University of Hawaii, Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Pôle Planétologie du LESIA, Laboratoire d'études spatiales et d'instrumentation en astrophysique = Laboratory of Space Studies and Instrumentation in Astrophysics (LESIA), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Università degli Studi di Padova = University of Padua (Unipd), and Jet Propulsion Laboratory, California Institute of Technology (JPL)

Subjects

chemistry.chemical_classification, Life on Titan, Astronomy and Astrophysics, Atmospheric sciences, Methane, Astrobiology, Troposphere, chemistry.chemical_compound, symbols.namesake, Hydrocarbon, chemistry, Space and Planetary Science, Carbon dioxide, symbols, Environmental science, Atmosphere of Titan, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph], Titan (rocket family), Stratosphere

Abstract

International audience; Methane is key to sustaining Titan's thick nitrogen atmosphere. However, methane is destroyed and converted to heavier hydrocarbons irreversibly on a relatively short timescale of approximately 10-100 million years. Without the warming provided by CH 4-generated hydrocarbon hazes in the stratosphere and the pressure induced opacity in the infrared, particularly by CH 4-N 2 and H 2-N 2 collisions in the troposphere, the atmosphere could be gradually reduced to as low as tens of millibar pressure. An understanding of the source-sink cycle of methane is thus crucial to the evolutionary history of Titan and its atmosphere. In this paper we propose that a complex photochemical-meteorological-hydrogeochemical cycle of methane operates on Titan. We further suggest that although photochemistry leads to the loss of methane from the atmosphere, conversion to a global ocean of ethane is unlikely. The behavior of methane in the troposphere and the surface, as measured by the Cassini-Huygens gas chromatograph mass spectrometer, together with evidence of cryovolcanism reported by the Cassini visual and infrared mapping spectrometer, represents a "methalogical" cycle on Titan, somewhat akin to the hydrological cycle on Earth. In the absence of net loss to the interior, it would represent a closed cycle. However, a source is still needed to replenish the methane lost to photolysis. A hydrogeochemical source deep in the interior of Titan holds promise. It is well known that in serpentinization, hydration of ultramafic silicates in terrestrial oceans produces H 2(aq), whose reaction with carbon grains or carbon dioxide in the crustal pores produces methane gas. Appropriate geological, thermal, and pressure conditions could have existed in and below Titan's purported water-ammonia ocean for "low-temperature" serpentinization to occur in Titan's accretionary heating phase. On the other hand, impacts could trigger the process at high temperatures. In either instance, storage of methane as a stable clathrate-hydrate in Titan's interior for later release to the atmosphere is quite plausible. There is also some likelihood that the production of methane on Titan by serpentinization is a gradual and continuous on-going process.

Published

2006

48. Impact cratering on Titan II. Global melt, escaping ejecta, and aqueous alteration of surface organics

Author

Natalia Artemieva and Jonathan I. Lunine

Subjects

Solar System, Astronomy and Astrophysics, Crust, Mantle (geology), Astrobiology, symbols.namesake, Impact crater, Space and Planetary Science, Hypervelocity, symbols, Atmosphere of Titan, Titan (rocket family), Ejecta, Geology

Abstract

New three-dimensional hydrodynamic simulations of hypervelocity impacts into the crust of Titan were undertaken to determine the fraction of liquid water generated on the surface of Saturn's largest moon over its history and, hence, the potential for surface—modification of hydrocarbons and nitriles by exposure to liquid water. We model in detail an individual impact event in terms of ejecta produced and melt generated, and use this to estimate melt production over Titan's history, taking into account the total flux of the impactors and its decay over time. Our estimates show that a global melt layer at any time after the very beginning of Titan's history is improbable; but transient melting local to newly formed craters has occurred over large parts of the surface. Local maxima of the melt are connected with the largest impact events. We also calculate the amount of volatiles delivered at the impact with various impact velocities (from 3 km/s for possible Hyperion fragments to 11 km/s for Jupiter family comets) and their retention as a possible source of Titan's atmosphere. We find the probability of impact ejecta escaping Titan with its modern dense and thick atmosphere is rather low, and dispersal of Titan organics throughout the rest of the Solar System requires impactors tens of kilometers in diameter. Water ice melting and exposure of organics to liquid water has been widespread because of impacts, but burial or obscuration of craters by organic deposits or cryovolcanism is aided by viscous relaxation. The largest impactors may breach an ammonia–water mantle layer, creating a circular albedo contrast rather than a crater.

Published

2005

49. Europa's Crust and Ocean: Origin, Composition, and the Prospects for Life

Author

Steven A. Grant, Jeffrey S. Kargel, James K. Crowley, Jonathan Z. Kaye, D. L. Hogenboom, Olga Prieto Ballesteros, Roger Sassen, James W. Head, and Giles M. Marion

Subjects

Clathrate hydrate, Geochemistry, Astronomy and Astrophysics, Crust, Hydrothermal circulation, Mantle (geology), chemistry.chemical_compound, chemistry, Space and Planetary Science, Chondrite, Carbonaceous chondrite, Sodium sulfate, Upwelling, Geology

Abstract

We have considered a wide array of scenarios for Europa's chemical evolution in an attempt to explain the presence of ice and hydrated materials on its surface and to understand the physical and chemical nature of any ocean that may lie below. We postulate that, following formation of the jovian system, the europan evolutionary sequence has as its major links: (a) initial carbonaceous chondrite rock, (b) global primordial aqueous differentiation and formation of an impure primordial hydrous crust, (c) brine evolution and intracrustal differentiation, (d) degassing of Europa's mantle and gas venting, (e) hydrothermal processes, and (f) chemical surface alteration. Our models were developed in the context of constraints provided by Galileo imaging, near infrared reflectance spectroscopy, and gravity and magnetometer data. Low-temperature aqueous differentiation from a carbonaceous CI or CM chondrite precursor, without further chemical processing, would result in a crust/ocean enriched in magnesium sulfate and sodium sulfate, consistent with Galileo spectroscopy. Within the bounds of this simple model, a wide range of possible layered structures may result; the final state depends on the details of intracrustal differentiation. Devolatilization of the rocky mantle and hydrothermal brine reactions could have produced very different ocean/crust compositions, e.g., an ocean/crust of sodium carbonate or sulfuric acid, or a crust containing abundant clathrate hydrates. Realistic chemical–physical evolution scenarios differ greatly in detailed predictions, but they generally call for a highly impure and chemically layered crust. Some of these models could lead also to lateral chemical heterogeneities by diapiric upwellings and/or cryovolcanism. We describe some plausible geological consequences of the physical–chemical structures predicted from these scenarios. These predicted consequences and observed aspects of Europa's geology may serve as a basis for further analys is and discrimination among several alternative scenarios. Most chemical pathways could support viable ecosystems based on analogy with the metabolic and physiological versatility of terrestrial microorganisms.

Published

2000

50. Dark Terrain on Ganymede: Geological Mapping and Interpretation of Galileo Regio at High Resolution

Author

Paul Helfenstein, Roland Wagner, Louise M. Prockter, Robert T. Pappalardo, Ursula Wolf, Ronald Greeley, Bernd Giese, David A. Senske, Clark R. Chapman, Gerhard Neukum, Jeffrey M. Moore, Jürgen Oberst, James W. Head, Michael J. S. Belton, and H. Herbert Breneman

Subjects

geography, geography.geographical_feature_category, Astronomy and Astrophysics, Crust, Massif, Mass wasting, Albedo, Geologic map, Tectonics, Impact crater, Space and Planetary Science, Ejecta, Geomorphology, Geology, Remote sensing

Abstract

During its first two encounters with Ganymede, the Galileo spacecraft obtained images of a 16,500 km 2 portion of Galileo Regio, a large expanse of dark terrain, at high resolution (76–86 m/pixel). Through mapping of the G1 and G2 target sites within Galileo Regio, we are able to characterize geological units based on their morphology and relative albedo. We find three generally low albedo units: an intermediate albedo plains unit, a lower albedo plains unit, and the lowest albedo unit which is found on furrow and crater floors. We also find high albedo units which include crater rims, furrow rims, and isolated knobs and massifs. Other features include an intermediate albedo lobate feature interpreted to be a palimpsest and a hummocky unit interpreted to be impact ejecta. Several processes are interpreted to have occurred within Galileo Regio. These include tectonic deformation, mass wasting, sublimation, resurfacing by impact ejecta, and possibly cryovolcanism and isostatic adjustment. We observe that the NW–SE trending furrows (Lakhmu Fossae) in Galileo Regio are degraded and are crosscut by the younger N–S trending furrows (Zu Fossae). We also find several other tectonic features which may be minor faults or fractures related to one or other of these systems. Through mapping and crater size–frequency distributions, we are able to propose a stratigraphy for the Galileo Regio target site. The oldest features in the area are high albedo knobs and massifs, which are interpreted to be remnants of early impact-related features and furrow rims. These may have formed at approximately the same time as the intermediate and low albedo plains units and the furrow systems. The lowest albedo unit of furrow floors probably subsequently evolved through sublimation and mass wasting. Much of the northeast portion of the target area was subsequently obscured by one of the youngest units, ejecta from an impact just to the north. We use our mapping of the high-resolution images of Galileo Regio to evaluate three end-member models for the formation of dark terrain: (1) the crust is dark throughout, (2) material on the surface is the result of a low albedo cryovolcanic layer over a higher albedo crust, and (3) dark material is distributed in small quantities throughout the crust, and geological processes have acted to concentrate low albedo material on the surface. Although it is possible that elements of more than one of these models are present within the dark terrain, we find that the third model, that of a thin veneer of low albedo material, best fits observations of Galileo Regio

Published

1998