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51. Terrestrial single-station analog for constraining the martian core and deep interior: Implications for InSight

Author

Maria E. Banks, Ingrid Daubar, Nicholas Schmerr, and Angela G. Marusiak

Subjects
Martian, Seismometer, 010504 meteorology & atmospheric sciences, Single station, Astronomy and Astrophysics, Induced seismicity, Geodesy, 01 natural sciences, Article, Mantle (geology), Azimuth, Amplitude, Recovery rate, Space and Planetary Science, 0103 physical sciences, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

We used a terrestrial single-station seismometer to quantify the uncertainty of InSight (INterior explorations using Seismic Investigations, Geodesy and Heat Transport) data for determining Martian core size. To mimic Martian seismicity, we formed a catalog using 917 terrestrial earthquakes, from which we randomly selected events. We stacked ScS amplitudes on modeled arrival times and searched for where ScS produced coherent seismic amplitudes. A core detection was defined by a coherent peak with small offset between predicted and user-selected arrival times. Iterating the detection algorithm with varying signal-to-noise (SNR) ranges and quantity of events determined the selection frequency of each model and quantified core depth uncertainty. Increasing the quantity of events reduced core depth uncertainty while increasing the recovery rate, while increasing event SNR had little effect. Including ScS2 multiples increased the recovery rate and reduced core depth uncertainty when we used low quantities of events. The most-frequent core depths varied by back azimuth, suggesting our method is sensitive to the presence of mantle heterogeneities. When we added 1° in source distance errors, core depth uncertainty increased by up to 11 km and recovery rates decreased by

Published
2020

52. Duration of activity on lobate‐scarp thrust faults on Mercury

Author

Zhiyong Xiao, Clark R. Chapman, Christian Klimczak, Thomas R. Watters, Paul K. Byrne, Maria E. Banks, Sean C. Solomon, S. E. Braden, and Robert G. Strom

Subjects
chemistry.chemical_element, Fault scarp, Mercury (element), Paleontology, Tectonics, Geophysics, chemistry, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Lithosphere, Planet, Earth and Planetary Sciences (miscellaneous), Thrust fault, human activities, Late Heavy Bombardment, Geomorphology, Geology
Abstract

Lobate scarps, landforms interpreted as the surface manifestation of thrust faults, are widely distributed across Mercury and preserve a record of its history of crustal deformation. Their formation is primarily attributed to the accommodation of horizontal shortening of Mercury's lithosphere in response to cooling and contraction of the planet's interior. Analyses of images acquired by the Mariner 10 and MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft during flybys of Mercury showed that thrust faults were active at least as far back in time as near the end of emplacement of the largest expanses of smooth plains. However, the full temporal extent of thrust fault activity on Mercury, particularly the duration of this activity following smooth plains emplacement, remained poorly constrained. Orbital images from the MESSENGER spacecraft reveal previously unrecognized stratigraphic relations between lobate scarps and impact craters of differing ages and degradation states. Analysis of these stratigraphic relations indicates that contraction has been a widespread and long-lived process on the surface of Mercury. Thrust fault activity had initiated by a time near the end of the late heavy bombardment of the inner solar system and continued through much or all of Mercury's subsequent history. Such deformation likely resulted from the continuing secular cooling of Mercury's interior.

Published
2015

53. Global thrust faulting on the Moon and the influence of tidal stresses

Author

Thomas R. Watters, Katie Daud, Geoffrey C. Collins, Mark S. Robinson, M. M. Selvans, Nathan R. Williams, and Maria E. Banks

Subjects
Graben, Current (stream), Tectonics, geography, geography.geographical_feature_category, Impact crater, Geology, Thrust fault, Crust, Fault (geology), Fault scarp, Seismology
Abstract

Lunar Reconnaissance Orbiter Camera images reveal a vast, globally distributed network of over 3200 lobate thrust fault scarps, making them the most common tectonic landform on the Moon. Based on their small scale and crisp appearance, crosscutting relations with small-diameter impact craters, and rates of infilling of associated small, shallow graben, these fault scarps are estimated to be younger than 50 Ma and may be actively forming today. The non-random distribution of the scarp orientations is inconsistent with isotropic stresses from late-stage global contraction as the sole source of stress. We propose that tidal stresses contribute significantly to the current stress state of the lunar crust. Orbital recession stresses superimposed on stresses from global contraction with the addition of diurnal tidal stresses result in non-isotropic compressional stress and thrust faults consistent with lobate scarp orientations. The addition of diurnal tidal stresses at apogee result in peak stresses that may help trigger coseismic slip events on currently active thrust faults on the Moon.

Published
2015

54. Geological and hydrological histories of the Argyre province, Mars

Author

Alberto G. Fairén, Jianguo Yan, Maria E. Banks, Goro Komatsu, H.J. Cleaves, Alfonso F. Davila, James M. Dohm, Jeffrey S. Kargel, Dirk Schulze-Makuch, Stuart J. Robbins, Brian M. Hynek, Jean-Pierre Williams, Susan J. Conway, Shigenori Maruyama, Hideaki Miyamoto, William C. Mahaney, Trent M. Hare, Wolfgang Fink, Debra Buczkowski, Richard J. Soare, Mohamed Ramy El-Maarry, Robert C. Anderson, Dawson College, Physikalisches Institut [Bern], Universität Bern [Bern], Open University (School of Physical Sciences), Washington State University (WSU), Center for Human Genetics, University of Leuven School of Medicine, SCHOOL of MEDICINE [Louvain], Université Catholique de Louvain = Catholic University of Louvain (UCL)-Université Catholique de Louvain = Catholic University of Louvain (UCL), aucun, Zentralanstalt für Meteorologie und Geodynamik (ZAMG), Institute of Fluid Sciences [Sendai] (IFS), and Tohoku University [Sendai]

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geochemistry, Drainage basin, Fluvial, Astronomy and Astrophysics, 15. Life on land, Structural basin, 01 natural sciences, [SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, Impact crater, 13. Climate action, Space and Planetary Science, 0103 physical sciences, Sedimentary rock, Glacial period, Ice sheet, [SDU.STU.AG]Sciences of the Universe [physics]/Earth Sciences/Applied geology, 010303 astronomy & astrophysics, ComputingMilieux_MISCELLANEOUS, Geology, 0105 earth and related environmental sciences, Tharsis
Abstract

The geologic history of the multi-ringed Argyre impact basin and surroundings has been reconstructed on the basis of geologic mapping and relative-age dating of rock materials and structures. The impact formed a primary basin, rim materials, and a complex basement structural fabric including faults and valleys that are radial and concentric about the primary basin, as well as structurally-controlled local basins. Since its formation, the basin has been a regional catchment for volatiles and sedimentary materials as well as a dominant influence on the flow of surface ice, debris flows, and groundwater through and over its basement structures. The basin is interpreted to have been occupied by lakes, including a possible Mediterranean-sized sea that formed in the aftermath of the Argyre impact event. The hypothesized lakes froze and diminished through time, though liquid water may have remained beneath the ice cover and sedimentation may have continued for some time. At its deepest, the main Argyre lake may have taken more than a hundred thousand years to freeze to the bottom even absent any heat source besides the Sun, but with impact-induced hydrothermal heat, geothermal heat flow due to long-lived radioactivities in early martian history, and concentration of solutes in sub-ice brine, liquid water may have persisted beneath thick ice for many millions of years. Existence of an ice-covered sea perhaps was long enough for life to originate and evolve with gradually colder and more hypersaline conditions. The Argyre rock materials, diverse in origin and emplacement mechanisms, have been modified by impact, magmatic, eolian, fluvial, lacustrine, glacial, periglacial, alluvial, colluvial, and tectonic processes.\ud \ud Post-impact adjustment of part of the impact-generated basement structural fabric such as concentric faults is apparent. Distinct basin-stratigraphic units are interpreted to be linked to large-scale geologic activity far from the basin, including growth of the Tharsis magmatic–tectonic complex and the growth into southern middle latitudes of south polar ice sheets. Along with the migration of surface and sub-surface volatiles towards the central part of the primary basin, the substantial difference in elevation with respect to the surrounding highlands and Tharsis and the Thaumasia highlands result in the trapping of atmospheric volatiles within the basin in the form of fog and regional or local precipitation, even today. In addition, the impact event caused long-term (millions of years) hydrothermal activity, as well as deep-seated basement structures that have tapped the internal heat of Mars, as conduits, for far greater time, possibly even today. This possibility is raised by the observation of putative open-system pingos and nearby gullies that occur in linear depressions with accompanying systems of faults and fractures. Long-term water and heat energy enrichment, complemented by the interaction of the nutrient-enriched primordial crustal and mantle materials favorable to life excavated to the surface and near-surface environs through the Argyre impact event, has not only resulted in distinct geomorphology, but also makes the Argyre basin a potential site of exceptional astrobiological significance.

Published
2015

55. Distribution of large‐scale contractional tectonic landforms on Mercury: Implications for the origin of global stresses

Author

Kris J. Becker, Steven A. Hauck, Maria E. Banks, M. M. Selvans, Thomas R. Watters, and Mark S. Robinson

Subjects
Tectonics, Geophysics, Lithosphere, Downwelling, Middle latitudes, General Earth and Planetary Sciences, Thrust fault, Spatial distribution, Fault scarp, Geomorphology, Geology, Mantle (geology)
Abstract

The surface of Mercury is dominated by contractional tectonic landforms that are evidence of global-scale crustal deformation. Using MESSENGER orbital high-incidence angle imaging and topographic data, large-scale lobate thrust fault scarps have been mapped globally. The spatial distribution and areal density of the contractional landforms are not uniform; concentrations occur in longitudinal bands and between the north and south hemispheres. Their orientations are generally north-south at low latitude to midlatitude and east-west at high latitudes. The spatial distribution and distribution of orientations of these large-scale contractional features suggest that planet-wide contraction due to interior cooling cannot be the sole source of global stresses. The nonrandom orientations are best explained by a combination of stresses from global contraction and tidal despinning combined with an equator-to-pole variation in lithospheric thickness, while the nonuniform areal density of the contractional features may indicate the influence of mantle downwelling or heterogeneities in lithospheric strength.

Published
2015

58. Bedform migration on Mars: Current results and future plans

Author

Maria E. Banks, Paul E. Geissler, Nathan P. Bridges, and Simone Silvestro

Subjects
geography, Bedform, geography.geographical_feature_category, Geology, Mars Exploration Program, Latitude, Erg (landform), Martian surface, Aeolian processes, Digital elevation model, Geomorphology, Change detection, Earth-Surface Processes
Abstract

With the advent of high resolution imaging, bedform motion can now be tracked on the Martian surface. HiRISE data, with a pixel scale as fine as 25 cm, shows displacements of sand patches, dunes, and ripples up to several meters per Earth year, demonstrating that significant landscape modification occurs in the current environment. This seems to consistently occur in the north polar erg, with variable activity at other latitudes. Volumetric dune and ripple changes indicate sand fluxes up to several cubic meters per meter per year, similar to that found in some dune fields on Earth. All “transverse aeolian ridges” are immobile. There is no relationship between bedform activity and coarse-scale global circulation models, indicating that finer scale topography and wind gusts, combined with the predicted low impact threshold on Mars, are the primary drivers. Several techniques have been developed to measure bedform changes and are largely dependent on dataset availability and the type of questions being pursued. Qualitative visual inspection can determine whether or not changes have occurred. Offsets registered to fixed tie points yield approximate migration rates of nearby crests and dune lee fronts. To compute volumetric sand flux requires precise orthorectification and registration using a digital elevation model base. Using this technique combined with sophisticated change detection software has the potential to detect changes as fine as 1/3 of a pixel (∼8 cm) or less.

Published
2013

59. Fault dislocation modeled structure of lobate scarps from Lunar Reconnaissance Orbiter Camera digital terrain models

Author

Nathan R. Williams, James F. Bell, Matthew E. Pritchard, Thomas R. Watters, and Maria E. Banks

Subjects
geography, geography.geographical_feature_category, Landform, Terrain, Mars Exploration Program, Geophysics, Fault (geology), Fault scarp, law.invention, Tectonics, Orbiter, Space and Planetary Science, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Thrust fault, Seismology, Geology
Abstract

[1] Before the launch of the Lunar Reconnaissance Orbiter, known characteristics of lobate scarps on the Moon were limited to studies of only a few dozen scarps revealed in Apollo-era photographs within ~20° of the equator. The Lunar Reconnaissance Orbiter Camera now provides meter-scale images of more than 100 lobate scarps, as well as stereo-derived topography of about a dozen scarps. High-resolution digital terrain models (DTMs) provide unprecedented insight into scarp morphology and dimensions. Here, we analyze images and DTMs of the Slipher, Racah X-1, Mandel'shtam-1, Feoktistov, Simpelius-1, and Oppenheimer F lobate scarps. Parameters in fault dislocation models are iteratively varied to provide best fits to DTM topographic profiles to test previous interpretations that the observed landforms are the result of shallow, low-angle thrust faults. Results suggest that these faults occur from the surface down to depths of hundreds of meters, have dip angles of 35–40°, and have typical maximum slips of tens of meters. These lunar scarp models are comparable to modeled geometries of lobate scarps on Mercury, Mars, and asteroid 433 Eros, but are shallower and ~10° steeper than geometries determined in studies with limited Apollo-era data. Frictional and rock mass strength criteria constrain the state of global differential stress between 3.5 and 18.6 MPa at the modeled maximum depths of faulting. Our results are consistent with thermal history models that predict relatively small compressional stresses that likely arise from cooling of a magma ocean.

Published
2013

61. Recent extensional tectonics on the Moon revealed by the Lunar Reconnaissance Orbiter Camera

Author

Thomas R. Watters, Brett W. Denevi, Mark S. Robinson, T. Tran, and Maria E. Banks

Subjects
Tectonics, Orbiter, Impact crater, law, General Earth and Planetary Sciences, Extensional tectonics, Geophysics, Extensional definition, Geology, Seismology, law.invention
Abstract

On the Moon, extensional tectonic features have only been observed close to the influence of the mare basalt-filled basins and floor-fractured craters. Analysis of Lunar Reconnaissance Orbiter Camera images reveals several potentially very young extensional tectonic features in the farside highlands, implying that extensional stresses may locally exceed compressional ones.

Published
2012

62. Mercury crater statistics from MESSENGER flybys: Implications for stratigraphy and resurfacing history

Author

William J. Merline, Louise M. Prockter, Caleb I. Fassett, Clark R. Chapman, Sean C. Solomon, Maria E. Banks, Jeffrey A. Forde, Robert G. Strom, and James W. Head

Subjects
education.field_of_study, geography, geography.geographical_feature_category, Population, chemistry.chemical_element, Astronomy and Astrophysics, Geophysics, Volcanism, Structural basin, Mercury (element), Paleontology, chemistry, Volcano, Impact crater, Space and Planetary Science, Geologic history, education, Late Heavy Bombardment, Geology
Abstract

The primary crater population on Mercury has been modified by volcanism and secondary craters. Two phases of volcanism are recognized. One volcanic episode that produced widespread intercrater plains occurred during the period of the Late Heavy Bombardment and markedly altered the surface in many areas. The second episode is typified by the smooth plains interior and exterior to the Caloris basin, both of which have a different crater size-frequency distribution than the intercrater plains, consistent with a cratering record dominated by a younger population of impactors. These two phases may have overlapped as parts of a continuous period of volcanism during which the volcanic flux tended to decrease with time. The youngest age of smooth plains volcanism cannot yet be determined, but at least small expanses of plains are substantially younger than the plains associated with the Caloris basin. The spatial and temporal variations of volcanic resurfacing events can be used to reconstruct Mercury's geologic history from images and compositional and topographic data to be acquired during the orbital phase of the MESSENGER mission.

Published
2011

63. Evidence of volcanic and glacial activity in Chryse and Acidalia Planitiae, Mars

Author

Sara Martínez-Alonso, Alfred S. McEwen, Michael T. Mellon, Maria E. Banks, and Laszlo P. Keszthelyi

Subjects
geography, geography.geographical_feature_category, Landform, Drumlin, Astronomy and Astrophysics, Context (language use), Mars Exploration Program, Columnar jointing, Paleontology, Volcano, Impact crater, Space and Planetary Science, Glacial period, Geology
Abstract

Chryse and Acidalia Planitiae show numerous examples of enigmatic landforms previously interpreted to have been influenced by a water/ice-rich geologic history. These landforms include giant polygons bounded by kilometer-scale arcuate troughs, bright pitted mounds, and mesa-like features. To investigate the significance of the last we have analyzed in detail the region between 60°N, 290°E and 10°N, 360°E utilizing HiRISE (High Resolution Imaging Science Experiment) images as well as regional-scale data for context. The mesas may be analogous to terrestrial tuyas (emergent sub-ice volcanoes), although definitive proof has not been identified. We also report on a blocky unit and associated landforms (drumlins, eskers, inverted valleys, kettle holes) consistent with ice-emplaced volcanic or volcano-sedimentary flows. The spatial association between tuya-like mesas, ice-emplaced flows, and further possible evidence of volcanism (deflated flow fronts, volcanic vents, columnar jointing, rootless cones), and an extensive fluid-rich substratum (giant polygons, bright mounds, rampart craters), allows for the possibility of glaciovolcanic activity in the region. Landforms indicative of glacial activity on Chryse/Acidalia suggest a paleoclimatic environment remarkably different from today’s. Climate changes on Mars (driven by orbital/obliquity changes) or giant outflow channel activity could have resulted in ice-sheet-related landforms far from the current polar caps.

Published
2011

64. Evidence of Recent Thrust Faulting on the Moon Revealed by the Lunar Reconnaissance Orbiter Camera

Author

Maria E. Banks, James F. Bell, Thomas R. Watters, Matthew E. Pritchard, Peter C. Thomas, Ross A. Beyer, Carolyn H. van der Bogert, Elizabeth P. Turtle, Mark S. Robinson, Harald Hiesinger, and Nathan R. Williams

Subjects
geography, Multidisciplinary, geography.geographical_feature_category, Landform, Apparent age, Fault scarp, law.invention, Graben, Orbiter, Tectonics, Impact crater, law, Thrust fault, Geology, Seismology
Abstract

Lunar Lobate Scarps Revealed Lunar lobate scarps are relatively small-scale landforms that are thought to be formed by tectonic thrust faulting. Previously, lunar lobate scarps could only be identified clearly in high-resolution Apollo Panoramic Camera images confined to the lunar equatorial zone. Now, an analysis by Watters et al. (p. 936 ) of images returned by the Lunar Reconnaissance Orbiter Camera reveals 14 previously unknown lobate scarps and shows that lunar lobate scarps may be globally distributed. Their appearance suggests that lunar scarps are relatively young landforms (less than 1 Ga), possibly formed during a recent episode of global lunar radial contraction.

Published
2010

65. Aeolian bedforms, yardangs, and indurated surfaces in the Tharsis Montes as seen by the HiRISE Camera: Evidence for dust aggregates

Author

Maria E. Banks, Frank C. Chuang, Lajos Keszthelyi, Timothy I. Michaels, Bradley J. Thomson, Kathryn E. Fishbaugh, Alfred S. McEwen, James J. Wray, Ross A. Beyer, Nathan T. Bridges, E. Z. Noe Dobrea, and K. E. Herkenhoff

Subjects
Katabatic wind, Bedform, Space and Planetary Science, Saltation (geology), Tharsis Montes, Aeolian processes, Astronomy and Astrophysics, Mars Exploration Program, Petrology, Yardang, Geology, Mantle (geology)
Abstract

HiRISE images of Mars with ground sampling down to 25 cm/pixel show that the dust-rich mantle covering the surfaces of the Tharsis Montes is organized into ridges whose form and distribution are consistent with formation by aeolian saltation. Other dusty areas near the volcanoes and elsewhere on the planet exhibit a similar morphology. The material composing these “reticulate” bedforms is constrained by their remote sensing properties and the threshold curve combined with the saltation/suspension boundary, both of which vary as a function of elevation (atmospheric pressure), particle size, and particle composition. Considering all of these factors, dust aggregates are the most likely material composing these bedforms. We propose that airfall dust on and near the volcanoes aggregates in situ over time, maybe due to electrostatic charging followed by cementation by salts. The aggregates eventually reach a particle size at which saltation is possible. Aggregates on the flanks are transported downslope by katabatic winds and form linear and “accordion” morphologies. Materials within the calderas and other depressions remain trapped and are subjected to multidirectional winds, forming an interlinked “honeycomb” texture. In many places on and near the volcanoes, light-toned, low thermal inertia yardangs and indurated surfaces are present. These may represent “duststone” formed when aggregates reach a particle size below the threshold curve, such that they become stabilized and subsequently undergo cementation.

Published
2010

66. The High Resolution Imaging Science Experiment (HiRISE) during MRO’s Primary Science Phase (PSP)

Author

Sarah Mattson, Maria E. Banks, Alfred S. McEwen, Donald G. Deardorff, G. McArthur, T. Forrester, Eric M. Eliason, Robert A. King, Steven W. Squyres, Bob Kanefsky, A. Fennema, Chris H. Okubo, Colin M. Dundas, John A. Grant, Edward Bortolini, M. L. Searls, A. K. Boyd, Richard Leis, Charlie Van Houten, Sara Martínez-Alonso, Laszlo P. Keszthelyi, Jeffrey Lasco, Eldar Noe Dobrea, K. J. Kolb, Shane Byrne, Bradley J. Thomson, Bradford Castalia, Timothy Spriggs, Yisrael Espinoza, James W. Bergstrom, Frank C. Chuang, A. T. Polit, Alaina DeJong, Steven Tarr, Ross A. Beyer, A. Lefort, R. Heyd, Candice Hansen, Andrea J. Philippoff, Albert Ortiz, John P. Grotzinger, Tahirih Motazedian, W. Alan Delamere, J. L. Griffes, Kris J. Becker, Nathan T. Bridges, Moses Milazzo, Dean Jones, Circe Verba, Patrick Russell, Catherine M. Weitz, N. Baugh, Joannah M. Metz, Virginia C. Gulick, Randolph L. Kirk, Joseph Plassmann, Windy L. Jaeger, Paul E. Geissler, Kenneth E. Herkenhoff, Livio L. Tornabene, Ingrid Daubar, Kathryn E. Fishbaugh, Michael T. Mellon, Nicolas Thomas, Larry S. Crumpler, Ralph E. Milliken, C. Schaller, Kevin W. Lewis, James J. Wray, and Alix K. Davatzes

Subjects
geography, geography.geographical_feature_category, Lava, Bedrock, Noachian, Pyroclastic rock, Astronomy and Astrophysics, Mars Exploration Program, Columnar jointing, Impact crater, Stratigraphy, Space and Planetary Science, Geomorphology, Geology, Remote sensing
Abstract

The High Resolution Imaging Science Experiment (HiRISE) on the Mars Reconnaissance Orbiter (MRO) acquired 8 terapixels of data in 9137 images of Mars between October 2006 and December 2008, covering ~0.55% of the surface. Images are typically 5–6 km wide with 3-color coverage over the central 20% of the swath, and their scales usually range from 25 to 60 cm/pixel. Nine hundred and sixty stereo pairs were acquired and more than 50 digital terrain models (DTMs) completed; these data have led to some of the most significant science results. New methods to measure and correct distortions due to pointing jitter facilitate topographic and change-detection studies at sub-meter scales. Recent results address Noachian bedrock stratigraphy, fluvially deposited fans in craters and in or near Valles Marineris, groundwater flow in fractures and porous media, quasi-periodic layering in polar and non-polar deposits, tectonic history of west Candor Chasma, geometry of clay-rich deposits near and within Mawrth Vallis, dynamics of flood lavas in the Cerberus Palus region, evidence for pyroclastic deposits, columnar jointing in lava flows, recent collapse pits, evidence for water in well-preserved impact craters, newly discovered large rayed craters, and glacial and periglacial processes. Of particular interest are ongoing processes such as those driven by the wind, impact cratering, avalanches of dust and/or frost, relatively bright deposits on steep gullied slopes, and the dynamic seasonal processes over polar regions. HiRISE has acquired hundreds of large images of past, present and potential future landing sites and has contributed to scientific and engineering studies of those sites. Warming the focal-plane electronics prior to imaging has mitigated an instrument anomaly that produces bad data under cold operating conditions.

Published
2010

67. A Closer Look at Water-Related Geologic Activity on Mars

Author

K. J. Kolb, Eric M. Eliason, Steven W. Squyres, Candice Hansen, J. L. Griffes, Scott L. Murchie, James J. Wray, Bradley J. Thomson, Lajos Keszthelyi, Patrick Russell, Michael T. Mellon, Shane Byrne, Frank C. Chuang, Nicolas Thomas, Kathryn E. Fishbaugh, Alexandra K. Davatzes, R. L. Kirk, Frank P. Seelos, Kimberly D. Seelos, M. P. Milazzo, Nathan T. Bridges, Kenneth E. Herkenhoff, Alfred S. McEwen, Catherine M. Weitz, John A. Grant, Virginia C. Gulick, Chris H. Okubo, Livio L. Tornabene, Maria E. Banks, Colin M. Dundas, Sara Martínez-Alonso, Windy L. Jaeger, and W. A. Delamere

Subjects
Geological Phenomena, geography, Multidisciplinary, geography.geographical_feature_category, Extraterrestrial Environment, Water on Mars, Landform, Earth science, Mars, Water, Fluvial, Geology, Mars Exploration Program, Snow, law.invention, Orbiter, Impact crater, law, Ravine
Abstract

Water has supposedly marked the surface of Mars and produced characteristic landforms. To understand the history of water on Mars, we take a close look at key locations with the High-Resolution Imaging Science Experiment on board the Mars Reconnaissance Orbiter, reaching fine spatial scales of 25 to 32 centimeters per pixel. Boulders ranging up to approximately 2 meters in diameter are ubiquitous in the middle to high latitudes, which include deposits previously interpreted as finegrained ocean sediments or dusty snow. Bright gully deposits identify six locations with very recent activity, but these lie on steep (20 degrees to 35 degrees) slopes where dry mass wasting could occur. Thus, we cannot confirm the reality of ancient oceans or water in active gullies but do see evidence of fluvial modification of geologically recent mid-latitude gullies and equatorial impact craters.

Published
2007

68. Morphometric analysis of small-scale lobate scarps on the Moon using data from the Lunar Reconnaissance Orbiter

Author

Nathan R. Williams, Mark S. Robinson, Maria E. Banks, Thomas R. Watters, Lujendra Ojha, Livio L. Tornabene, and T. Tran

Subjects
Atmospheric Science, Ecology, Equator, Paleontology, Soil Science, Forestry, Mars Exploration Program, Aquatic Science, Oceanography, Geodesy, Fault scarp, law.invention, Tectonics, Orbiter, Geophysics, Space and Planetary Science, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Thrust fault, Altimeter, Scale (map), Geology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Prior to Lunar Reconnaissance Orbiter (LRO), the morphology and dimensions of only a limited number of lobate scarps, all located near the equator (within 21°), had been characterized. Topography derived from LRO Camera stereo images and Lunar Orbiter Laser Altimeter (LOLA) ranging is used to measure the relief and analyze the morphology of previously known and newly detected low and high latitude lobate scarps. The asymmetric profiles and maximum slopes on scarp faces (∼5° to 29°) of lunar lobate scarps are similar to those of lobate scarps observed on Mars and Mercury. Scarp lengths range from ∼0.6 to 21.6 km (mean = ∼6.0 km, median = ∼4.4 km, n = 79), and measured relief ranges from ∼5 to 150 m (mean = ∼35 m, median = ∼20 m, n = 26). Assuming a range of 20° to 40° for the fault plane dip, estimated lower limits for the horizontal shortening (S) expressed by the lobate scarp thrust faults range from ∼10 to 410 m. The range in S estimated for the lunar scarps is roughly an order of magnitude lower than estimates of S for lobate scarp thrust faults on Mars and Mercury. The relatively small range of S estimated for the growing number of well-characterized lunar scarps is consistent with a small amount of global contraction.

Published
2012

69. Crater population and resurfacing of the Martian north polar layered deposits

Author

Alfred S. McEwen, Bruce C. Murray, Kenneth E. Herkenhoff, Maria E. Banks, Colin M. Dundas, Shane Byrne, Kathryn E. Fishbaugh, Veronica J. Bray, and Kapil Galla

Subjects
Atmospheric Science, Population, Soil Science, Context (language use), Aquatic Science, Oceanography, Spatial distribution, law.invention, Orbiter, Impact crater, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), education, Geomorphology, Earth-Surface Processes, Water Science and Technology, Remote sensing, Martian, education.field_of_study, Ecology, Paleontology, Forestry, Mars Exploration Program, Geophysics, Space and Planetary Science, Polar, Geology
Abstract

Present-day accumulation in the north polar layered deposits (NPLD) is thought to occur via deposition on the north polar residual cap. Understanding current mass balance in relation to current climate would provide insight into the climatic record of the NPLD. To constrain processes and rates of NPLD resurfacing, a search for craters was conducted using images from the Mars Reconnaissance Orbiter Context Camera. One hundred thirty craters have been identified on the NPLD, 95 of which are located within a region defined to represent recent accumulation. High Resolution Imaging Science Experiment images of craters in this region reveal a morphological sequence of crater degradation that provides a qualitative understanding of processes involved in crater removal. A classification system for these craters was developed based on the amount of apparent degradation and infilling and where possible depth/diameter ratios were determined. The temporal and spatial distribution of crater degradation is interpreted to be close to uniform. Through comparison of the size-frequency distribution of these craters with the expected production function, the craters are interpreted to be an equilibrium population with a crater of diameter D meters having a lifetime of ~30.75D^(1.14) years. Accumulation rates within these craters are estimated at 7.2D^(−0.14) mm/yr, which corresponds to values of ~3–4 mm/yr and are much higher than rates thought to apply to the surrounding flat terrain. The current crater population is estimated to have accumulated in the last ~20 kyr or less.

Published
2010

70. An analysis of sinuous ridges in the southern Argyre Planitia, Mars using HiRISE and CTX images and MOLA data

Author

Robert G. Strom, Alfred S. McEwen, Maria E. Banks, Nicholas P. Lang, John A. Grant, Victor R. Baker, Jon D. Pelletier, and Jeffrey S. Kargel

Subjects
Atmospheric Science, Water flow, Soil Science, Context (language use), Aquatic Science, Oceanography, law.invention, Orbiter, Mola, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Glacial period, Geomorphology, Earth-Surface Processes, Water Science and Technology, geography, geography.geographical_feature_category, Ecology, biology, Paleontology, Forestry, Mars Exploration Program, Geophysics, biology.organism_classification, Space and Planetary Science, Ridge, Mars Orbiter Laser Altimeter, Geology
Abstract

[1] A suite of sinuous ridges with branching and braided morphologies forms an anastomosing network in southern Argyre Planitia, Mars. Several modes of origin have been proposed for the Argyre ridges. Imagery from the High Resolution Imaging Science Experiment (HiRISE) and Context Camera (CTX) aboard Mars Reconnaissance Orbiter (MRO) and Mars Orbiter Laser Altimeter (MOLA) topographic data sets from Mars Global Surveyor (MGS) are used to constrain processes involved in formation of the Argyre ridges. We find the characteristics of the ridges and associated layered deposits consistent with glaciofluvial-lacustrine processes and conclude that the ridges are most likely eskers. In particular, variations in ridge height appear to be related to the surrounding surface slope; ridge height increases with descending slopes and decreases with ascending slopes. This characteristic is observed in terrestrial eskers and is related to subice flow processes. The nature of some eroding beds in the ridges suggests induration. If the Argyre ridges are indeed eskers, the southern Argyre basin was once covered by the margin of a large, thick, stagnating or retreating ice deposit that extended for hundreds of kilometers or more. During ridge formation, water flowed on top, within, or beneath the ice deposit; the continuity and preservation of the ridges suggests that flow was primarily at the base of the ice. The dimensions (up to hundreds of meters tall and several kilometers wide), aspect ratio, and extent (hundreds of kilometers) of the ridges, as well as preliminary calculations of discharge, suggest that a significant amount of water was available.

Published
2009

71. High Resolution Imaging Science Experiment (HiRISE) observations of glacial and periglacial morphologies in the circum-Argyre Planitia highlands, Mars

Author

Alfred S. McEwen, Robert G. Strom, Jon D. Pelletier, Maria E. Banks, Jeffrey S. Kargel, Michael T. Mellon, Victor R. Baker, Kenneth E. Herkenhoff, Laszlo P. Keszthelyi, Virginia C. Gulick, and Windy L. Jaeger

Subjects
Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Landform, Paleontology, Soil Science, Rock glacier, Forestry, Glacier, Aquatic Science, Oceanography, Debris, Geophysics, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Moraine, Earth and Planetary Sciences (miscellaneous), Glacial period, Geomorphology, Geology, Earth-Surface Processes, Water Science and Technology, Patterned ground
Abstract

[1] The landscape of the Argyre Planitia and adjoining Charitum and Nereidum Montes in the southern hemisphere of Mars has been heavily modified since formation of the Argyre impact basin. This study examines morphologies in the Argyre region revealed in images acquired by the High Resolution Imaging Science Experiment (HiRISE) camera and discusses the implications for glacial and periglacial processes. Distinctive features such as large grooves, semicircular embayments in high topography, and streamlined hills are interpreted as glacially eroded grooves, cirques, and whalebacks or roche moutonnee, respectively. Large boulders scattered across the floor of a valley may be ground moraine deposited by ice ablation. Glacial interpretations are supported by the association of these features with other landforms typical of glaciated landscapes such as broad valleys with parabolic cross sections and stepped longitudinal profiles, lobate debris aprons interpreted as remnant debris covered glaciers or rock glaciers, and possible hanging valleys. Aligned boulders observed on slopes may also indicate glacial processes such as fluting. Alternatively, boulders aligned on slopes and organized in clumps and polygonal patterns on flatter surfaces may indicate periglacial processes, perhaps postglaciation, that form patterned ground. At least portions of the Argyre region appear to have been modified by processes of ice accumulation, glacial flow, erosion, sediment deposition, ice stagnation and ablation, and perhaps subsequent periglacial processes. The type of bedrock erosion apparent in images suggests that glaciers were, at times, wet based. The number of superposed craters is consistent with geologically recent glacial activity, but may be due to subsequent modification.

Published
2008

72. Forward modeling of ice topography on Mars to infer basal shear stress conditions

Author

Maria E. Banks and Jon D. Pelletier

Subjects
Martian, Atmospheric Science, Ecology, Paleontology, Soil Science, Greenland ice sheet, Forestry, Mars Exploration Program, Aquatic Science, Pressure ridge, Oceanography, Geophysics, Sea ice growth processes, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Shear stress, Digital elevation model, Geomorphology, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Understanding the history of ice caps on Mars could reveal important information about Martian geologic and climatic history. To do this, an ice reconstruction model is needed that operates over complex topography and can be constrained with a limited number of free parameters. In this study we developed a threshold-sliding model for ice cap morphology based on the classic model of Nye later incorporated into the models of Reeh and colleagues. We have updated the Nye-Reeh model with a new numerical algorithm. Although the model was originally developed to model perfectly plastic deformation, it is applicable to any ice body that deforms when a threshold basal shear stress is exceeded. The model requires three inputs: a digital elevation model of bed topography, a “mask” grid that defines the position of the ice terminus, and a function defining the threshold basal shear stress. To test the robustness of the model, the morphology of the Greenland ice sheet is reconstructed using an empirical equation between threshold basal shear stress and ice surface slope. The model is then used to reconstruct the morphology of ice draping impact craters on the margins of the south polar layered deposits using an inferred constant basal shear stress of ∼0.6 bar for the majority of the examples. This inferred basal shear stress value is almost 1/3 of the average basal shear stress calculated for the Greenland ice sheet. What causes this lower basal shear stress value on Mars is unclear but could involve the strain-weakening behavior of ice.

Published
2008

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