Your search keyword '"Maria E. Banks"' showing total 11 results

1. Comparative Planetology – Comparing Cirques on Mars and Earth Using a Cnn

Author

Joshua Williams, Louis Scuderi, Timothy P. McClanahan, Maria E. Banks, and David M. H. Baker

Published

2023

2. Wrinkle ridges on Mercury and the Moon within and outside of mascons

Author

Thomas R. Watters, L. S. Schleicher, Aaron J. Martin, and Maria E. Banks

Subjects

Basalt, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Lunar mare, Anticline, Astronomy and Astrophysics, 01 natural sciences, Volcano, Space and Planetary Science, Lithosphere, 0103 physical sciences, medicine, Terrestrial planet, Thrust fault, medicine.symptom, 010303 astronomy & astrophysics, Geomorphology, Wrinkle, Geology, 0105 earth and related environmental sciences

Abstract

Found on all terrestrial planets, wrinkle ridges are anticlines formed by thrust faulting and folding resulting from crustal shortening. The MErcury Surface, Space Environment, Geochemistry, and Ranging (MESSENGER) spacecraft's orbital phase returned high resolution images and topographic data of the previously unimaged northern high latitudes of Mercury where there are large expanses of smooth plains deformed by wrinkle ridges. Concurrently, the Lunar Reconnaissance Orbiter (LRO) is obtaining high resolution images and topographic data covering lunar mare wrinkle ridges. These data allow quantitative comparison of the scale of wrinkle ridges in smooth plains volcanic units on Mercury with mare wrinkle ridges. We evaluate the topographic relief of 300 wrinkle ridges within and outside of mascon basins on the Moon and Mercury. Measured wrinkle ridges range from ~112 to 776 m in relief with a mean of ~350 m (median = ~340 m, n = 150) on Mercury and from ~47 to 678 m in relief with a mean of ~198 m (median = ~168 m, n = 150) on the Moon. Wrinkle ridges on Mercury thus are approximately twice as large in mean relief compared to their counterparts on the Moon. The larger scale of Mercury's wrinkle ridges suggests that their formation can be attributed, in part, to global contraction. As global contraction on the Moon is estimated to be an order of magnitude smaller than on Mercury, the smaller scale of lunar wrinkle ridges suggests they most likely form primarily by load induced subsidence of the mare basalt. Wrinkle ridges located in lunar mascon basins and in the Caloris mascon on Mercury are not statistically significantly different in relief than ridges in non-mascon regions, suggesting comparable levels of contractional strain. The fact that mascon basins do not host wrinkle ridges with greater structural relief relative to non-mascon units may indicate the critical role lithospheric thickness plays in controlling subsidence and contraction of thick volcanic sequences on the Moon and Mercury.

Published

2019

3. Evidence for recent and ancient faulting at Mare Frigoris and implications for lunar tectonic evolution

Author

James F. Bell, Renee A. French, Maria E. Banks, Thomas R. Watters, Nathan R. Williams, and Katie Daud

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Landform, Astronomy and Astrophysics, Induced seismicity, Fault scarp, 01 natural sciences, Billion years, Graben, Paleontology, Global population, Tectonics, Space and Planetary Science, Ridge, 0103 physical sciences, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Nearside basin-related extensional tectonism on the Moon was thought to have ended by about 3.6 billion years ago and mare basin-localized contractional deformation ended by about 1.2 billion years ago. Lunar Reconnaissance Orbiter Camera (LROC) high resolution (50–200 cm/pixel) images show the Moon's surface in unprecedented detail and have enabled us to find many previously unidentified tectonic landforms, forcing a re-assessment of our views of tectonism in the maria. The morphology and stratigraphic relationships of these newly identified populations of tectonic landforms imply a more complex and longer-lasting history of deformation. We selected Mare Frigoris as an ideal location to perform a mapping survey where excellent imaging conditions, abundant tectonic landforms, and restricted mascon allow us to unravel the mare's tectonic evolution. Similar to previous surveys, we find that tectonism in the eastern portion of Mare Frigoris was controlled by ancient mascon induced flexure. In the western portion, however, we identify a parallel set of ancient compressional wrinkle ridges across the mare that is inconsistent with an origin by mare basin-centric mascon flexure or influence from the Mare Imbrium mascon. Instead, our results imply an ancient, regional, non-isotropic stress field over western Mare Frigoris. We also identify young wrinkle ridges and show that they have likely been active within the last 1 billion years, and some ridges as recently as within 40 million years. Finally, we identify a 300 km long series of lobate scarps coincident with one of the shallow moonquakes recorded during Apollo and use geodetic strain from the mapped global population of young lobate scarps to predict a level of seismicity consistent with the shallow moonquakes recorded during Apollo. In tandem with similarly young lobate scarps and small graben, as well as recorded shallow moonquakes, these young wrinkle ridges imply that some tectonism in and around Mare Frigoris has occurred in the geologically recent past and likely still continues today.

Published

2019

4. How old are lunar lobate scarps? 1. Seismic resetting of crater size-frequency distributions

Author

Maria E. Banks, Mark S. Robinson, Harald Hiesinger, Thomas R. Watters, J. D. Clark, and Carolyn H. van der Bogert

Subjects

Ground motion, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Landform, Astronomy and Astrophysics, Fault (geology), Fault scarp, 01 natural sciences, Graben, Paleontology, Tectonics, Impact crater, Space and Planetary Science, 0103 physical sciences, Size frequency, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Previous studies have estimated the ages of lunar lobate scarps, some of the youngest tectonic landforms on the Moon, based on the estimated life-times of their fresh morphologies and associated small graben, using crater degradation ages, or via buffered and traditional crater size-frequency distribution (CSFD) measurements. Here, we reexamine five scarps previously dated by Binder and Gunga (1985) with crater degradation ages to benchmark the evaluation of both the buffered and traditional CSFD approaches for determination of absolute model ages (AMAs) at scarps. Both CSFD methods yield similar ages for each individual scarp, indicating that fault activity not only can be measured on the scarp itself, but also in the surrounding terrain – an indication that tectonic activity causes surface renewal both adjacent to and even kilometers distant from scarps. Size-frequency variations in the regions surrounding the scarps are thus useful for studying the extent and severity of the ground motion caused by coseismic slip events during scarp formation. All age determination approaches continue to indicate that lunar lobate scarps were active in the late Copernican, with some scarps possibly experiencing activity within the last 100 Ma.

Published

2018

5. 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

6. 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

7. 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

8. 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

9. 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

10. 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

11. 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