Your search keyword '"Victor R. Baker"' showing total 17 results

1. Did the martian outflow channels mostly form during the Amazonian Period?

Author

N. H. Glines, Alberto G. Fairén, J. Alexis P. Rodriguez, Virginia C. Gulick, Victor R. Baker, Jeffrey S. Kargel, Jianguo Yan, Thomas Platz, and Hideaki Miyamoto

Subjects

Martian, geography, geography.geographical_feature_category, Bedform, Amazonian, Astronomy and Astrophysics, Glacier, Debris, Paleontology, 13. Climate action, Space and Planetary Science, Erosion, Hesperian, Outflow, Geology

Abstract

Simud, Tiu, and Ares Valles comprise some of the largest outflow channels on Mars. Their excavation has been attributed variously to (or a combination of) erosion by catastrophic floods, glaciers, and debris flows. Numerous investigations indicate that they formed largely during the Late Hesperian (3.61–3.37 Ga). However, these studies mostly equate the ages of the outflow channel floors to those of the flows that generated mesoscale (several hundred meters to a few kilometers) bedforms within them. To improve the statistical accuracy in the age determinations of these flow events, we have used recently acquired high-resolution image and topographic data to map and date portions of Simud, Tiu and Ares Valles, which are extensively marked by these bedforms. Our results, which remove the statistical effects of older and younger outflow channel floor surfaces on the generation of modeled ages, reveal evidence for major outflow channel discharges occurring during the Early (3.37–1.23 Ga) and Middle (1.23–0.328 Ga) Amazonian, with activity significantly peaking during the Middle Amazonian stages. We also find that during the documented stages of Middle Amazonian discharges, the floor of Tiu Valles underwent widespread collapse, resulting in chaotic terrain formation. In addition, we present evidence showing that following the outflow channel discharges, collapse within northern Simud Valles generated another chaotic terrain. This younger chaos region likely represents the latest stage of large-scale outflow channel resurfacing within the study area. Our findings imply that in southern circum-Chryse the martian hydrosphere experienced large-scale drainage during the Amazonian, which likely led to periodic inundation and sedimentation within the northern plains.

Published

2015

2. New insights into the Late Amazonian zonal shrinkage of the martian south polar plateau

Author

Virginia C. Gulick, Hideaki Miyamoto, Alberto G. Fairén, Thomas Platz, Kenneth L. Tanaka, Gregory J. Leonard, J. Alexis P. Rodriguez, N. H. Glines, Jeffrey S. Kargel, Victor R. Baker, Midori Oguma, and Yan Jianguo

Subjects

Martian, geography, Paleontology, Plateau, geography.geographical_feature_category, Space and Planetary Science, Planet, Amazonian, Polar, Astronomy and Astrophysics, Geology, Astrobiology

Abstract

The martian south polar plateau, Planum Australe, comprises the largest known water–ice surface deposit on the planet. Here, we present evidence for an episode of extensive polar plateau retreat during the Late Amazonian, which affected regions flanking circum-polar terrains located between Cavi Angusti and Sisyphi Montes.

Published

2015

3. Evidence for Middle Amazonian catastrophic flooding and glaciation on Mars

Author

Thomas Platz, Virginia C. Gulick, J. W. Rice, Hideaki Miyamoto, Jeffrey S. Kargel, Alberto G. Fairén, Victor R. Baker, N. H. Glines, and J. Alexis P. Rodriguez

Subjects

geography, geography.geographical_feature_category, Landform, Amazonian, Astronomy and Astrophysics, Glacier, Mars Exploration Program, Debris, Paleontology, Impact crater, Space and Planetary Science, Outflow, Glacial period, Geology

Abstract

Early geologic investigations of Mars revealed some of the largest channels in the Solar System (outflow channels), which appear to have mostly developed ∼3 byr ago. These channels have been the subject of much scientific inquiry since the 1970s and proposed formative processes included surface erosion by catastrophic floods, glaciers, debris flows and lava flows. Based on the analysis of newly acquired Mars Reconnaissance Orbiter (MRO) Context (CTX, 5.15–5.91 m/pixel) and High Resolution Imaging Science Experiment (HiRISE, 25–50 cm/pixel) image data, we have identified a few locations contained within relatively narrow canyons of the southern circum-Chryse outflow channels that retain well-preserved decameter/hectometer-scale landform assemblages. These terrains include landforms consistent in shape, dimension and overall assemblage to those produced by catastrophic floods, and at one location, to glacial morphologies. Impact crater statistics for four of these surfaces, located within upstream, midstream and downstream outflow channel surfaces, yield an age estimate of ∼600 myr. This suggests that the southern circum-Chryse outflow channels were locally resurfaced by some of the most recent catastrophic floods on the planet, and that these floods coexisted within regional glacier environments as recently as during the Middle Amazonian.

Published

2014

4. Secondary chaotic terrain formation in the higher outflow channels of southern circum-Chryse, Mars

Author

Roberto Furfaro, Sho Sasaki, David A. Crown, J. Alexis P. Rodriguez, Kenneth L. Tanaka, Pat Candelaria, Victor R. Baker, Jeffrey S. Kargel, Daniel C. Berman, and Alberto G. Fairén

Subjects

Martian, geography, geography.geographical_feature_category, Amazonian, Astronomy and Astrophysics, Mars Exploration Program, Regolith, Impact crater, Volcano, Space and Planetary Science, Hesperian, Outflow, Petrology, Geology

Abstract

Higher outflow channel dissection in the martian region of southern circum-Chryse appears to have extended from the Late Hesperian to the Middle Amazonian Epoch. These outflow channels were excavated within the upper 1 km of the cryolithosphere, where no liquid water is expected to have existed during these geologic epochs. In accordance with previous work, our examination of outflow channel floor morphologies suggests the upper crust excavated by the studied outflow channels consisted of a thin (a few tens of meters) layer of dry geologic materials overlying an indurated zone that extends to the bases of the investigated outflow channels (1 km in depth). We find that the floors of these outflow channels contain widespread secondary chaotic terrains (i.e., chaotic terrains produced by the destruction of channel-floor materials). These chaotic terrains occur within the full range of outflow channel dissection and tend to form clusters. Our examination of the geology of these chaotic terrains suggests that their formation did not result in the generation of floods. Nevertheless, despite their much smaller dimensions, these chaotic terrains are comprised of the same basic morphologic elements (e.g., mesas, knobs, and smooth deposits within scarp-bound depressions) as those located in the initiation zones of the outflow channels, which suggests that their formation must have involved the release of ground volatiles. We propose that these chaotic terrains developed not catastrophically but gradually and during multiple episodes of nested surface collapse. In order to explain the formation of secondary chaotic terrains within zones of outflow channel dissection, we propose that the regional Martian cryolithosphere contained widespread lenses of volatiles in liquid form. In this model, channel floor collapse and secondary chaotic terrain formation would have taken place as a consequence of instabilities arising during their exhumation by outflow channel dissection. Within relatively warm upper crustal materials in volcanic settings, or within highly saline crustal materials where cryopegs developed, lenses of volatiles in liquid form within the cryolithosphere could have formed, and/or remained stable. In addition, our numerical simulations suggest that low thermal conductivity, dry fine-grained porous geologic materials just a few tens of meters in thickness (e.g., dunes, sand sheets, some types of regolith materials), could have produced high thermal anomalies resulting in subsurface melting. The existence of a global layer of dry geologic materials overlying the cryolithosphere would suggest that widespread lenses of fluids existed (and may still exist) at shallow depths wherever these materials are fine-grained and porous. The surface ages of the investigated outflow channels and chaotic terrains span a full 500 to 700 Myr. Chaotic terrains similar in dimensions and morphology to secondary chaotic terrains are not observed conspicuously throughout the surface of Mars, suggesting that intra-cryolithospheric fluid lenses may form relatively stable systems. The existence of widespread groundwater lenses at shallow depths of burial has tremendous implications for exobiological studies and future human exploration. We find that the clear geomorphologic anomaly that the chaotic terrains and outflow channels of southern Chryse form within the Martian landscape could have been a consequence of large-scale resurfacing resulting from anomalously extensive subsurface melt in this region of the planet produced by high concentrations of salts within the regional upper crust. Crater count statistics reveal that secondary chaotic terrains and the outflow channels within which they occur have overlapping ages, suggesting that the instabilities leading to their formation rapidly dissipated, perhaps as the thickness of the cryolithosphere was reset following the disruption of the upper crustal thermal structure produced during outflow channel excavation.

Published

2011

5. A geomorphic analysis of Hale crater, Mars: The effects of impact into ice-rich crust

Author

H. J. Melosh, Livio L. Tornabene, Victor R. Baker, Daniel C. Berman, A. P. Jones, and Alfred S. McEwen

Subjects

Martian, Impact crater, Space and Planetary Science, Martian surface, Noachian, Astronomy and Astrophysics, Crust, Mars Exploration Program, Petrology, Ejecta, Geology, Debris flow, Astrobiology

Abstract

Hale crater, a 125 × 150 km impact crater located near the intersection of Uzboi Vallis and the northern rim of Argyre basin at 35.7°S, 323.6°E, is surrounded by channels that radiate from, incise, and transport material within Hale’s ejecta. The spatial and temporal relationship between the channels and Hale’s ejecta strongly suggests the impact event created or modified the channels and emplaced fluidized debris flow lobes over an extensive area (>200,000 km2). We estimate ∼1010 m3 of liquid water was required to form some of Hale’s smaller channels, a volume we propose was supplied by subsurface ice melted and mobilized by the Hale-forming impact. If 10% of the subsurface volume was ice, based on a conservative porosity estimate for the upper martian crust, 1012 m3 of liquid water could have been present in the ejecta. We determine a crater-retention age of 1 Ga inside the primary cavity, providing a minimum age for Hale and a time at which we propose the subsurface was volatile-rich. Hale crater demonstrates the important role impacts may play in supplying liquid water to the martian surface: they are capable of producing fluvially-modified terrains that may be analogous to some landforms of Noachian Mars.

Published

2011

6. Possible ancient giant basin and related water enrichment in the Arabia Terra province, Mars

Author

Robert C. Anderson, Kris Kerry, Victor R. Baker, Trent M. Hare, James M. Dohm, Alberto G. Fairén, J. A. P. Rodriguez, J. C. Ferris, Nadine G. Barlow, G. Jeffrey Taylor, Jean-Pierre Williams, Hirdy Miyamoto, Robert G. Strom, William V. Boynton, John Keller, and Daniel M. Janes

Subjects

Martian, Geologic province, Impact crater, Space and Planetary Science, Geochemistry, Noachian, Astronomy and Astrophysics, Sedimentary rock, Mars Exploration Program, Structural basin, Geology, Tharsis, Astrobiology

Abstract

A circular albedo feature in the Arabia Terra province was first hypothesized as an ancient impact basin using Viking-era information. To test this unpublished hypothesis, we have analyzed the Viking era-information together with layers of new data derived from the Mars Global Surveyor (MGS) and Mars Odyssey (MO) missions. Our analysis indicates that Arabia Terra is an ancient geologic province of Mars with many distinct characteristics, including predominantly Noachian materials, a unique part of the highland–lowland boundary, a prominent paleotectonic history, the largest region of fretted terrain on the planet, outflow channels with no obvious origins, extensive exposures of eroded layered sedimentary deposits, and notable structural, albedo, thermal inertia, gravity, magnetic, and elemental signatures. The province also is marked by special impact crater morphologies, which suggest a persistent volatile-rich substrate. No one characteristic provides definitive answers to the dominant event(s) that shaped this unique province. Collectively the characteristics reported here support the following hypothesized sequence of events in Arabia Terra: (1) an enormous basin, possibly of impact origin, formed early in martian history when the magnetic dynamo was active and the lithosphere was relatively thin, (2) sediments and other materials were deposited in the basin during high erosion rates while maintaining isostatic equilibrium, (3) sediments became water enriched during the Noachian Period, and (4) basin materials were uplifted in response to the growth of the Tharsis Bulge, resulting in differential erosion exposing ancient stratigraphic sequences. Parts of the ancient basin remain water-enriched to the present day.

Published

2007

7. The role of arcuate ridges and gullies in the degradation of craters in the Newton Basin region of Mars

Author

Victor R. Baker, William K. Hartmann, David A. Crown, and Daniel C. Berman

Subjects

Solar System, Quadrangle, Impact crater, Space and Planetary Science, Planet, Astronomy and Astrophysics, Mars global surveyor, Mars Exploration Program, Structural basin, Geomorphology, Geology, Astrobiology, Latitude

Abstract

A survey of craters in the vicinity of Newton Basin, using high-resolution images from Mars Global Surveyor and Mars Odyssey, was conducted to find and analyze examples of gullies and arcuate ridges and assess their implications for impact crater degradation processes. In the Phaethontis Quadrangle (MC-24), we identified 225 craters that contain these features. Of these, 188 had gullies on some portion of their walls, 118 had arcuate ridges at the bases of the crater walls, and 104 contained both features, typically on the same crater wall. A major result is that the pole-facing or equator-facing orientation of these features is latitude dependent. At latitudes >44° S, equator-facing orientations for both ridges and gullies are prevalent, but at latitudes

Published

2005

8. Ancient wet aeolian environments on Earth: clues to presence of fossil/live microorganisms on Mars

Author

David Malloch, Goro Komatsu, William C. Mahaney, James M. Dohm, Victor R. Baker, Dennis I. Netoff, Trent M. Hare, Hideaki Miyamoto, and Michael W. Milner

Subjects

Martian, Space and Planetary Science, Martian surface, Geochemistry, Aeolian processes, Sediment, Astronomy and Astrophysics, Sedimentary rock, Mars Exploration Program, Silt, Clay minerals, Geology

Abstract

Ancient wet aeolian (wet-sabkha) environments on Earth, represented in the Entrada and Navajo sandstones of Utah, contain pipe structures considered to be the product of gas/water release under pressure. The sediments originally had considerable porosity allowing the ingress of living plant structures, microorganisms, clay minerals, and fine-grained primary minerals of silt and sand size from the surface downward in the sedimentary column. Host rock material is of a similar size and porosity and presumably the downward migration of fine-grained material would have been possible prior to lithogenesis and final cementation. Recent field emission scanning electron microscopy (FESEM) and EDS (energy-dispersive spectrometry) examination of sands from fluidized pipes in the Early Jurassic Navajo Sandstone reveal the presence of fossil forms resembling fungal filaments, some bearing hyphopodium-like structures similar to those produced by modern tropical leaf parasites. The tropical origin of the fungi is consistent with the paleogeography of the sandstone, which was deposited in a tropical arid environment. These fossil fungi are silicized, with minor amounts of CaCO 3 and Fe, and in some cases a Si/Al ratio similar to smectite. They exist as pseudomorphs, totally depleted in nitrogen, adhering to the surfaces of fine-grained sands, principally quartz and orthoclase. Similar wet aeolian paleoenvironments are suspected for Mars, especially following catastrophic sediment-charged floods of enormous magnitudes that are believed to have contributed to rapid formation of large water bodies in the northern plains, ranging from lakes to oceans. These events are suspected to have contributed to a high frequency of constructional landforms (also known as pseudocraters) related to trapped volatiles and water-enriched sediment underneath a thick blanket of materials that were subsequently released to the martian surface, forming piping structures at the near surface and constructional landforms at the surface. This constructional process on Mars may help unravel the complex history of some of the piping structures observed on Earth; on Earth, evidence for the constructional landforms has been all but erased and the near-surface piping structures exposed through millions of years of differential erosion and topographic inversion now occur as high-standing promontories. If the features on both Earth and Mars formed by similar processes, especially involving water and other volatiles, and since the piping structures of Earth provided suitable environments for life to thrive in, the martian features in the northern plains should be considered as prime targets for physico/mineral/chemical/microbiological analyses once the astrobiological exploration of the red planet begins in earnest.

Published

2004

9. Tectonic histories between Alba Patera and Syria Planum, Mars

Author

Albert F. C. Haldemann, James M. Dohm, Victor R. Baker, Trent M. Hare, and Robert C. Anderson

Subjects

biology, Amazonian, Noachian, Astronomy and Astrophysics, Patera, Mars Exploration Program, Geologic map, biology.organism_classification, Graben, Paleontology, Space and Planetary Science, Hesperian, Geology, Tharsis

Abstract

Syria Planum and Alba Patera are two of the most prominent features of magmatic-driven activity identified for the Tharsis region and perhaps for all of Mars. In this study, we have performed a Geographic Information System-based comparative investigation of their tectonic histories using published geologic map information and Mars Orbiter Laser Altimetry (MOLA) data. Our primary objective is to assess their evolutional histories by focusing on their extent of deformation in space and time through stratigraphic, paleotectonic, topographic, and geomorphologic analyses. Though there are similarities among the two prominent features, there are several distinct differences, including timing deformational extent, and tectonic intensity of formation. Whereas Alba Patera displays a major pulse of activity during the Late Hesperian/Early Amazonian, Syria Planum is a long-lived center that displays a more uniform distribution of simple graben densities ranging from the Noachian to the Amazonian, many of which occur at greater distances away from the primary center of activity. The histories of the two features presented here are representative of the complex, long-lived evolutional history of Tharsis.

Published

2004

10. Episodic flood inundations of the northern plains of Mars

Author

Javier Ruiz, James M. Dohm, Miguel Ángel de Pablo, Victor R. Baker, Robert C. Anderson, Alberto G. Fairén, and J. C. Ferris

Subjects

geography, geography.geographical_feature_category, Amazonian, Noachian, Drainage basin, Astronomy and Astrophysics, Aquifer, Paleontology, Olympus Mons, Space and Planetary Science, Mars Orbiter Laser Altimeter, Hesperian, Geology, Tharsis

Abstract

Throughout the recorded history of Mars, liquid water has distinctly shaped its landscape, including the prominent circum-Chryse and the northwestern slope valleys outflow channel systems, and the extremely flat northern plains topography at the distal reaches of these outflow channel systems. Paleotopographic reconstructions of the Tharsis magmatic complex reveal the existence of an Europe-sized Noachian drainage basin and subsequent aquifer system in eastern Tharsis. This basin is proposed to have sourced outburst floodwaters that sculpted the outflow channels, and ponded to form various hypothesized oceans, seas, and lakes episodically through time. These floodwaters decreased in volume with time due to inadequate groundwater recharge of the Tharsis aquifer system. Martian topography, as observed from the Mars Orbiter Laser Altimeter, corresponds well to these ancient flood inundations, including the approximated shorelines that have been proposed for the northern plains. Stratigraphy, geomorphology, and topography record at least one great Noachian-Early Hesperian northern plains ocean, a Late Hesperian sea inset within the margin of the high water marks of the previous ocean, and a number of widely distributed minor lakes that may represent a reduced Late Hesperian sea, or ponded waters in the deepest reaches of the northern plains related to minor Tharsis- and Elysium-induced Amazonian flooding.

Published

2003

11. Morphogenesis of Antarctic Paleosols: Martian Analogue

Author

Iain B. Campbell, David Malloch, D. Sheppard, Horton E. Newsom, William C. Mahaney, Victor R. Baker, Michael W. Milner, Ronald G.V. Hancock, and James M. Dohm

Subjects

Total organic carbon, geography, geography.geographical_feature_category, fungi, Geochemistry, Astronomy and Astrophysics, Weathering, Paleosol, Deposition (aerosol physics), Space and Planetary Science, Soil water, Temperate climate, Environmental science, Ice sheet, Chemical composition

Abstract

Samples of horizons in paleosols from the Quartermain Mountains of the Antarctic Dry Valleys (Aztec and New Mountain areas) were analyzed for their physical characteristics, mineralogy, chemical composition, and microbiology to determine the accumulation and movement of salts and other soluble constituents and the presence/absence of microbial populations. Salt concentrations are of special interest because they are considered to be a function of age, derived over time, in part from nearby oceanic and high-altitude atmospheric sources. The chemical composition of ancient Miocene-age paleosols in these areas is the direct result of the deposition and weathering of airborne-influxed salts and other materials, as well as the weathering of till derived principally from local dolerite and sandstone outcrops. Paleosols nearer the coast have greater contents of Cl, whereas near the inland ice sheet, nitrogen tends to increase on a relative basis. The accumulation and vertical distribution of salts and other soluble chemical elements indicate relative amounts of movement in the profile over long periods of time, in the order of several million years. Four of the six selected subsamples from paleosol horizons in two ancient soil profiles contained nil concentrations of bacteria and fungi. However, two horizons at depths of between 3 and 8 cm, in two profiles, yielded several colonies of the fungi Beauveria bassiana and Penicillium brevicompactum , indicating very minor input of organic carbon. Beauveria bassiana is often reported in association with insects and is used commercially for the biological control of some insect pests. Penicillium species are commonly isolated from Arctic, temperate, and tropical soils and are known to utilize a wide variety of organic carbon and nitrogen compounds. The cold, dry soils of the Antarctic bear a close resemblance to various present and past martian environments where similar weathering could occur and possible microbial populations may exist.

Published

2001

12. Plains Tectonism on Venus: Inferences from Canali Longitudinal Profiles

Author

Goro Komatsu and Victor R. Baker

Subjects

geography, geography.geographical_feature_category, biology, Astronomy and Astrophysics, Venus, Deformation (meteorology), biology.organism_classification, Lower limit, Tectonics, Space and Planetary Science, Ridge, Tectonic deformation, Intraplate earthquake, Scale (map), Seismology, Geology

Abstract

Canali-type channels on Venus show inverted profile segments; that is, large portions of the channels trend uphill. The original gradients for these channels were not horizontal, but must have progressively trended downhill. Therefore, undulation patterns imposed on the profiles have to be the result of tectonism occurring since channel formation. This implies that some of the uppermost geological units of the plains, which are coincident with canali, experienced significant postemplacement tectonic deformation. The pattern of deformation is hierarchical. Within observational limits, at least two scales of deformation are indicated. The longer scale deformation (thousands of kilometers) corresponds to large-scale basins; the shorter scale deformation (hundreds of kilometers) corresponds to ridge belts or to small-scale domes/basins. The latter features, at scales up to a few hundred kilometers, extensively deform some plain areas. Although not appearing in the topographic profiles because of resolution limitations, deformation scales of tens of kilometers or less, which mostly reflect wrinkle ridges, also overlap the longer deformation scales. The channels probably formed relatively quickly in comparison to the time scale of deformation. Canali formation is closely related to the genesis of plains, and canali profile deformation reflects tectonic processes operating at multiple scales. The lower limit rates of large-scale tectonic warping are comparable to epeirogenetic deformation rates for Earth's intraplate continental interiors.

Published

1994

13. Surface Property Variations in Venusian Fluidized Ejecta Blanket Craters

Author

Jeffrey R. Johnson and Victor R. Baker

Subjects

biology, Lava, Astronomy and Astrophysics, Venus, Geophysics, biology.organism_classification, Impact crater, Space and Planetary Science, Radar imaging, Surface roughness, Emissivity, Ejecta blanket, Ejecta, Geology, Remote sensing

Abstract

A comprehensive study of Magellan Cycles 1 and 2 radar data from Venus reveals surface roughness and dielectric variations associated with fluidized ejecta blanket (FEB) craters that help illuminate styles of flow ejecta emplacement. This study develops new procedures of digital unit mapping and polygon-filling algorithms using Magellan synthetic aperture radar (SAR), altimetry, and radiometry data. These techniques allow the extraction of radiophysical information for FEB crater materials, nearby plains, and lava flows. Backscatter curve slopes of the FEBs studied here are consistent with surface textures that are transitional between a'a and pahoehoe-like. Average surface property values of ejecta units are relatively similar for a given crater, but are discernibly different from other craters. Individual crater ejecta reflectivity and emissivity values are relatively similar to those for the surrounding plains, which may suggest a link between plains material and ejecta dielectric properties. Increasing FEB roughness downflow are interpreted to be associated with more lava-like flows, while decreasing roughness are more similar to trends typical of gravity (pyroclastic-like or debris-like) flows. Most commonly, FEB crater flow materials exhibit transitions from proximal, lava/melt-like flow styles to distal, gravity flow-like styles. Some FEBs show more complicated behavior, however, or appear to be more dominated by dielectric differences downflow, as inferred from correlations between the data sets. Such transitions may result from changes in local topography or from overlapping of flow lobes during FEB emplacement.

Published

1994

14. The Volcanology of Venera and VEGA Landing Sites and the Geochemistry of Venus

Author

Robert G. Strom, Jeffrey S. Kargel, Goro Komatsu, and Victor R. Baker

Subjects

Basalt, Planetary science, biology, Space and Planetary Science, Oceanic crust, Magma, Geochemistry, Astronomy and Astrophysics, Crust, Igneous differentiation, Venus, biology.organism_classification, Mantle (geology)

Abstract

Magellan images confirm volcanic interpretations of television panoramas and geochemical data obtained by Venera and VEGA landers. Magellan and Venera/VEGA data are consistent with mafic volcanic compositions at all seven landing sites, although such compositions were proven at only three sites. Rock analyses show an unexpectedly high fraction of potassium-rich lavas. If the seven Venera and VEGA samples are approximately representative of the upper crust, just 10 km of the average material distributed globally would contain as much potassium as contained in Earth's continental and oceanic crust. Despite the likelihood that Venus' crust is overwhelmingly mafic, in terms of highly incompatible elements it may represent the differentiated magmatic equivalent of Earth's granitoid continents and of the Moon's anorthositic highlands. Although associated tectonic and petrogenetic aspects of lunar and Venusian crustal genesis were different, crust-forming processes on both objects (and possibly early terrestrial continent formation) may have involved cataclysmic partial melting of large fractions of these planets' mantles. A fairly mafic alkaline character of Venus' crust is attributed to a generally anhydrous, carbonated composition of Venus' mantle, which contrasts with a generally uncarbonated and variably hydrated composition of Earth's mantle. Aside from this important difference, Venus' mantle is geochemically almost identical to Earth's and is distinct from all other planetary objects for which compositional data exist. The compositional similarity of the mantles of Venus and Earth implies that the combined geochemical effects of nebular condensation, planetary accretion, and core formation were not substantially different for these planets.

Published

1993

15. Venusian Channels and Valleys: Distribution and Volcanological Implications

Author

Virginia C. Gulick, Timothy J. Parker, Victor R. Baker, and Goro Komatsu

Subjects

geography, geography.geographical_feature_category, Rift, Lava, Astronomy and Astrophysics, Volcanology, Volcanism, Mantle plume, Paleontology, Volcano, Space and Planetary Science, Rille, Rift zone, Geology

Abstract

An updated map is presented which shows the distribution of more than 200 channels and valleys on Venus. A large number of channels are concentrated in equatorial regions characterized by highlands, rift and fracture zones, an associated volcanic features. Many channels associated with flow deposits are similar to typical terrestrial lava drainage channels. They are associated with a wide range of volcanic edifices. More than half of the sinuous rilles are associated with coronae, coronalike features, or arachnoids. Corona volcanism driven by mantle plume events may explain this association. Many valley network are observed in highlands and in association with coronae, coronalike features, or arachnoids. This indicates that highlands and coronae provided fractures and flow-viscosity lavas, both of which seem to be required for network formation by lava sapping processes. Canali-type channels have a unique distribution limited to some plains regions.

Published

1993

16. Erratum to 'New insights into the Late Amazonian zonal shrinkage of the Martian south polar plateau' [Icarus 248 (2015) 407–411]

Author

Hideaki Miyamoto, Virginia C. Gulick, Thomas Platz, Gregory J. Leonard, Yan Jianguo, Kenneth L. Tanaka, J. Alexis P. Rodriguez, N. H. Glines, Victor R. Baker, Alberto G. Fairén, Jeffrey S. Kargel, and Midori Oguma

Subjects

Martian, ICARUS, geography, Plateau, geography.geographical_feature_category, Space and Planetary Science, Amazonian, Polar, Astronomy and Astrophysics, Geology, Astrobiology, Shrinkage

Published

2015

17. Erosion by catastrophic floods on Mars and Earth

Author

Daniel J. Milton and Victor R. Baker

Subjects

Martian, Pleistocene, Space and Planetary Science, Erosion, Astronomy and Astrophysics, Groundwater sapping, Mars Exploration Program, Mars surface, Chryse Planitia, Geomorphology, Geology, Deposition (geology), Remote sensing

Abstract

The morphologic features of the large Martian channels are shown to be strikingly similar to those of the Channeled Scabland of eastern Washington, produced by the catastrophic breakout floods of Pleistocene Lake Missoula. If the analogy is correct, floods involving water discharges of millions of cubic meters per second and peak flow velocities of tens of meters per second, but perhaps lasting no more than a few days, may have occurred on Mars.

Published

1974