Your search keyword '"Christopher S. Edwards"' showing total 32 results

1. Emirates Mars Mission Characterization of Mars Atmosphere Dynamics and Processes

Author

Hessa Almatroushi, Hoor AlMazmi, Noora AlMheiri, Mariam AlShamsi, Eman AlTunaiji, Khalid Badri, Robert J. Lillis, Fatma Lootah, Maryam Yousuf, Sarah Amiri, David A. Brain, Michael Chaffin, Justin Deighan, Christopher S. Edwards, Francois Forget, Michael D. Smith, Michael J. Wolff, Philip R. Christensen, Scott England, Matthew Fillingim, Gregory M. Holsclaw, Sonal Jain, Andrew R. Jones, Mikki Osterloo, Bruce M. Jakosky, Janet G. Luhmann, and Roland M. B. Young

Subjects

Space and Planetary Science, Astronomy and Astrophysics

Abstract

The Emirates Mars Mission (EMM) – Hope Probe – was developed to understand Mars atmospheric circulation, dynamics, and processes through characterization of the Mars atmosphere layers and its interconnections enabled by a unique high-altitude (19,970 km periapse and 42,650 km apoapse) low inclination orbit that will offer an unprecedented local and seasonal time coverage over most of the planet. EMM has three scientific objectives to (A) characterize the state of the Martian lower atmosphere on global scales and its geographic, diurnal and seasonal variability, (B) correlate rates of thermal and photochemical atmospheric escape with conditions in the collisional Martian atmosphere, and (C) characterize the spatial structure and variability of key constituents in the Martian exosphere. The EMM data products include a variety of spectral and imaging data from three scientific instruments measuring Mars at visible, ultraviolet, and infrared wavelengths and contemporaneously and globally sampled on both diurnal and seasonal timescale. Here, we describe our strategies for addressing each objective with these data in addition to the complementary science data, tools, and physical models that will facilitate our understanding. The results will also fill a unique role by providing diagnostics of the physical processes driving atmospheric structure and dynamics, the connections between the lower and upper atmospheres, and the influences of these on atmospheric escape.

Published

2021

2. Evaluating Flat‐Crater Floor Fill Compositions and Morphologies: Insight Into Formation Processes

Author

C. Pan, A. D. Rogers, and Christopher S. Edwards

Subjects

Geophysics, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Petrology, Geology

Published

2021

3. Specific Heat Capacity Measurements of Selected Meteorites for Planetary Surface Temperature Modeling

Author

Laurence A.J. Garvie, Tuan H. Vu, Christopher S. Edwards, Sylvain Piqueux, J. Bapst, and Mathieu Choukroun

Subjects

Geophysics, Materials science, Planetary surface, Meteorite, Thermal inertia, Space and Planetary Science, Geochemistry and Petrology, Thermophysics, Earth and Planetary Sciences (miscellaneous), Heat capacity, Astrobiology

Published

2021

4. Mapping and Characterization of Martian Intercrater Bedrock Plains: Insights Into Resurfacing Processes in the Martian Cratered Highlands

Author

Christopher S. Edwards, J. C. Cowart, and A. D. Rogers

Subjects

Martian, geography, Geophysics, geography.geographical_feature_category, Space and Planetary Science, Geochemistry and Petrology, Bedrock, Earth and Planetary Sciences (miscellaneous), Mars Exploration Program, Geology, Characterization (materials science), Astrobiology

Published

2019

5. Low-temperature specific heat capacity measurements and application to Mars thermal modeling

Author

Christopher S. Edwards, Philip R. Christensen, Timothy D. Glotch, Mathieu Choukroun, Tuan H. Vu, and Sylvain Piqueux

Subjects

Martian, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Bedrock, Mineralogy, Astronomy and Astrophysics, Mars Exploration Program, 01 natural sciences, Heat capacity, Volcanic rock, Thermal conductivity, Space and Planetary Science, 0103 physical sciences, Thermal, Sedimentary rock, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Data returned from Martian missions have revealed a wide diversity of surface mineralogies, including in geological structures interpreted to be sedimentary or altered by liquid water. These terrains are of great interest because of their potential to document the environment at a time when life may have appeared. Intriguingly, Martian sedimentary rocks show distinctly low thermal inertia values (i.e. 300 - 700 Jm−2K−1s−1/2, indicative of a combination of low thermal conductivity, specific heat capacity, and density). These low values are difficult to reconcile with their competent bedrock morphologies, whereas hundreds of bedrock occurrences, interpreted as volcanic in origin, have been mapped globally and display thermal inertia values > 1200 Jm−2K−1s−1/2. Bedrock thermal inertia values are generally assumed to be driven by their bulk thermal conductivity, which in turn is controlled by their micro- and macro-physical properties (i.e., degree and style of cementation in the case of detritic rocks, horizontal fractures and layering, etc.), and not by their density (well-known from terrestrial analog measurements, and with modest variability) or specific heat capacity (generally uncharacterized for non-basaltic materials below room temperature). In this paper, we demonstrate that specific heat capacity cannot be a potential cause for the differential thermophysical behavior between magmatic and sedimentary rocks through a series of experimental Cp(T) measurements at 100–350 K using differential scanning calorimetry. The results on 20 Martian-relevant minerals investigated in this work indicate that these materials exhibit very similar specific heats, ranging from 0.3–0.7 Jg−1K−1 at 100 K to 0.6–1.7 Jg−1K−1 at 350 K. When used in a Martian thermal model, this range of Cp values translate to very small surface temperature differences, indicating that uncertainty in composition (and its effect on the specific heat) is not a noticeable source of thermal inertia variability for indurated units on Mars. We therefore conclude that the low thermal inertia value of sedimentary rocks compared to magmatic/volcanic rocks is likely due to their low apparent bulk conductivity, which bears information on their internal physical structure. Future work combining the analysis of thermal observations acquired at various local times and seasons will help further characterize this heterogeneity.

Published

2019

6. Spectral evidence for a pyroclastic mantle over the Tacquet formation and Menelaus domes of southwest Mare Serenitatis

Author

William H. Farrand, Christopher S. Edwards, and Christian Tai Udovicic

Subjects

Space and Planetary Science, Astronomy and Astrophysics

Published

2022

7. Olivine and carbonate-rich bedrock in Gusev crater and the Nili Fossae region of Mars may be altered ignimbrite deposits

Author

Steven W. Ruff, Victoria E. Hamilton, A. Deanne Rogers, Christopher S. Edwards, and Briony H.N. Horgan

Subjects

Space and Planetary Science, Astronomy and Astrophysics

Published

2022

8. Thermophysical Properties and Surface Heterogeneity of Landing Sites on Mars From Overlapping Thermal Emission Imaging System (THEMIS) Observations

Author

Christopher S. Edwards, Sylvain Piqueux, A. Deanne Rogers, and Alexandra A. Ahern

Subjects

Surface (mathematics), Geophysics, Thermal inertia, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Thermal Emission Imaging System, Mars Exploration Program, Geology

Published

2021

9. Diagenesis Revealed by Fine‐Scale Features at Vera Rubin Ridge, Gale Crater, Mars

Author

Marie J. Henderson, Erwin Dehouck, Connor R. Tinker, Frances Rivera-Hernandez, Lauren A. Edgar, Nathan Stein, Briony Horgan, Abigail A. Fraeman, Linda C. Kah, Kenneth S. Edgett, Kristen A. Bennett, Amy J. Williams, Christopher S. Edwards, R. E. Kronyak, Deirdra M. Fey, Laboratoire de Géologie de Lyon - Terre, Planètes, Environnement (LGL-TPE), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), and Université de Lyon-Université de Lyon-Institut national des sciences de l'Univers (INSU - CNRS)-Université Jean Monnet - Saint-Étienne (UJM)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Geophysics, Scale (ratio), [SDU]Sciences of the Universe [physics], Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Ridge (meteorology), Gale crater, Mars Exploration Program, Geomorphology, Geology, Diagenesis

Abstract

International audience; Fine scale (submillimeter to centimeter) depositional and diagenetic features encountered during the Curiosity rover's traverse in Gale crater provide a means to understand the geologic history of Vera Rubin ridge (VRR). VRR is a topographically high feature on the lower north slope of Aeolis Mons, a 5 km high stratified mound within Gale crater. We use high spatial resolution images from the Mars Hand Lens Imager (MAHLI) as well as grain sizes estimated with the Gini index mean score technique that uses ChemCam Laser Induced Breakdown Spectroscopy (LIBS) chemical data to constrain the postdepositional history of the strata exposed on this ridge. MAHLI images were used to examine the color, grain size, and style of lamination of the host rocks, as well as to explore the occurrence of nodules, diagenetic crystals, pits, and a variety of dark gray iron rich features. This survey revealed abundant and widespread diagenetic features within the rocks exposed on VRR and demonstrated that rock targets estimated to be coarser generally contain more diagenetic features than those estimated to have finer grains, which indicate that grain size may have influenced the degree and type of diagenesis. A subset of rocks within VRR are gray in color and exhibit the highest proportion of diagenetic features. We suggest that these targets experienced a different diagenetic history than the other rocks on VRR and hypothesize that redistribution and recrystallization of iron within specific intervals may have resulted in both the gray color and the abundance of dark gray iron rich diagenetic features.

Published

2021

10. The Emirates Mars Mission (EMM) Emirates Mars InfraRed Spectrometer (EMIRS) Instrument

Author

Eman Al Tunaiji, Mark J. Miner, Emily B. Pilinski, Carlos A. Ortiz, Aaron Weintraub, Tara Fisher, K. E. Powell, Rob Woodward, Igor Lazbin, Christopher S. Edwards, Ken Shamordola, Nathan Smith, D. Pelham, Tom Tourville, S. Anwar, Andrew Holmes, Philip R. Christensen, Heather Reed, Zoltan Farkas, G. L. Mehall, Michael D. Smith, William O’Donnell, Heather Bowles, S. C. Chase, Mark McAdam, Edgar Madril, Mehul Patel, Kelly Harris-Laurila, Ian Kubik, John Janiczek, and Khalid Badri

Subjects

Materials science, Atmosphere, business.industry, Aperture, Mars, Cassegrain reflector, Emirates Mars Infrared Spectrometer, Astronomy and Astrophysics, Mars Exploration Program, Article, Interferometry, Optics, Space and Planetary Science, Martian surface, Nadir, Radiance, EMM, business, Radiometric calibration

Abstract

The Emirates Mars Mission Emirates Mars Infrared Spectrometer (EMIRS) will provide remote measurements of the martian surface and lower atmosphere in order to better characterize the geographic and diurnal variability of key constituents (water ice, water vapor, and dust) along with temperature profiles on sub-seasonal timescales. EMIRS is a FTIR spectrometer covering the range from 6.0-100+ μm (1666-100 cm−1) with a spectral sampling as high as 5 cm−1 and a 5.4-mrad IFOV and a 32.5×32.5 mrad FOV. The EMIRS optical path includes a flat 45° pointing mirror to enable one degree of freedom and has a +/- 60° clear aperture around the nadir position which is fed to a 17.78-cm diameter Cassegrain telescope. The collected light is then fed to a flat-plate based Michelson moving mirror mounted on a dual linear voice-coil motor assembly. An array of deuterated L-alanine doped triglycine sulfate (DLaTGS) pyroelectric detectors are used to sample the interferogram every 2 or 4 seconds (depending on the spectral sampling selected). A single 0.846 μm laser diode is used in a metrology interferometer to provide interferometer positional control, sampled at 40 kHz (controlled at 5 kHz) and infrared signal sampled at 625 Hz. The EMIRS beamsplitter is a 60-mm diameter, 1-mm thick 1-arcsecond wedged chemical vapor deposited diamond with an antireflection microstructure to minimize first surface reflection. EMIRS relies on an instrumented internal v-groove blackbody target for a full-aperture radiometric calibration. The radiometric precision of a single spectrum (in 5 cm−1 mode) is −8 W cm−2 sr−1/cm−1 between 300 and 1350 cm−1 over instrument operational temperatures ($\Delta $ Δ T @ 250 K). The absolute integrated radiance error is < 2% for scene temperatures ranging from 200-340 K. The overall EMIRS envelope size is 52.9×37.5×34.6 cm and the mass is 14.72 kg including the interface adapter plate. The average operational power consumption is 22.2 W, and the standby power consumption is 18.6 W with a 5.7 W thermostatically limited, always-on operational heater. EMIRS was developed by Arizona State University and Northern Arizona University in collaboration with the Mohammed bin Rashid Space Centre with Arizona Space Technologies developing the electronics. EMIRS was integrated, tested and radiometrically calibrated at Arizona State University, Tempe, AZ.

Published

2020

11. Ancient Martian Aeolian Sand Dune Deposits Recorded in the Stratigraphy of Valles Marineris and Implications for Past Climates

Author

Lauren A. Edgar, Matthew Chojnacki, M. J. Jodhpurkar, Aaron Weintraub, Lori K. Fenton, and Christopher S. Edwards

Subjects

Martian, Geophysics, Stratigraphy, Space and Planetary Science, Geochemistry and Petrology, Aeolian sand, Earth and Planetary Sciences (miscellaneous), Geochemistry, Geology, Sand dune stabilization

Published

2020

12. Evidence for a diagenetic origin of vera rubin ridge, gale crater, Mars: summary and synthesis of curiosity's exploration campaign

Author

Craig Hardgrove, Kirsten L. Siebach, John P. Grotzinger, Christopher S. Edwards, Alexander B. Bryk, Susanne P. Schwenzer, Sarah Stewart Johnson, William E. Dietrich, Lauren A. Edgar, Sunetra Gupta, Steven G. Banham, Jeffrey G. Catalano, S. Czarnecki, K. M. Stack, Ashwin R. Vasavada, R. V. Morris, Danika Wellington, John Bridges, Christopher H. House, Kristen A. Bennett, S. M. R. Turner, David M. Rubin, Jonas L'Haridon, Jeffrey R. Johnson, Roger C. Wiens, Valerie Fox, S. Jacob, Raymond E. Arvidson, Amy J. Williams, Vivian Z. Sun, Christopher M. Fedo, Jens Frydenvang, Travis Gabriel, Briony Horgan, Woodward W. Fischer, E. B. Rampe, Abigail A. Fraeman, Lucy M. Thompson, N. Mangold, G. M. Wong, Mark R. Salvatore, Nathaniel Stein, G. David, Science and Technology Facilities Council (STFC), UK Space Agency, Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Laboratoire de Planétologie et Géodynamique [UMR 6112] (LPG), Université d'Angers (UA)-Université de Nantes - UFR des Sciences et des Techniques (UN UFR ST), and Université de Nantes (UN)-Université de Nantes (UN)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Geochemistry & Geophysics, 010504 meteorology & atmospheric sciences, Outcrop, Lacustrine, Geochemistry, [SDU.ASTR.EP]Sciences of the Universe [physics]/Astrophysics [astro-ph]/Earth and Planetary Astrophysics [astro-ph.EP], Mars, Hematite, FLUID-FLOW, Geologic record, 01 natural sciences, Diagenesis, Geochemistry and Petrology, 0201 Astronomical and Space Sciences, Earth and Planetary Sciences (miscellaneous), 0402 Geochemistry, CHEMCAM INSTRUMENT SUITE, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Spectral signature, Science & Technology, SEDIMENTARY-ROCKS, MOUNT SHARP, Bedrock, DYNAMIC ALBEDO, Gale crater, Mars Exploration Program, MURRAY FORMATION, 15. Life on land, ATOM EXCHANGE, Geophysics, Curiosity, 0403 Geology, Space and Planetary Science, visual_art, Physical Sciences, visual_art.visual_art_medium, PAHRUMP HILLS, (U-TH)/HE DATES, Geology

Abstract

This paper provides an overview of the Curiosity rover's exploration at Vera Rubin ridge and summarizes the science results. Vera Rubin ridge (VRR) is a distinct geomorphic feature on lower Aeolis Mons (informally known as Mt. Sharp) that was identified in orbital data based on its distinct texture, topographic expression, and association with a hematite spectral signature. Curiosity conducted extensive remote sensing observations, acquired data on dozens of contact science targets, and drilled three outcrop samples from the ridge, as well as one outcrop sample immediately below the ridge. Our observations indicate that strata composing VRR were deposited in a predominantly lacustrine setting and are part of the Murray formation. The rocks within the ridge are chemically in family with underlying Murray formation strata. Red hematite is dispersed throughout much of the VRR bedrock, and this is the source of the orbital spectral detection. Gray hematite is also present in isolated, gray‐colored patches concentrated towards the upper elevations of VRR, and these gray patches also contain small, dark Fe‐rich nodules. We propose that VRR formed when diagenetic event(s) preferentially hardened rocks, which were subsequently eroded into a ridge by wind. Diagenesis also led to enhanced crystallization and/or cementation that deepened the ferric‐related spectral absorptions on the ridge, which helped make them readily distinguishable from orbit. Results add to existing evidence of protracted aqueous environments at Gale crater and give new insight into how diagenesis shaped Mars’ rock record.

Published

2020

13. Bulk mineralogy of the NE Syrtis and Jezero crater regions of Mars derived through thermal infrared spectral analyses

Author

Philip R. Christensen, Christopher S. Edwards, Joshua L. Bandfield, Mark R. Salvatore, M. S. Bramble, E. S. Amador, J. F. Mustard, and Timothy A. Goudge

Subjects

Basalt, Olivine, Spectral signature, 010504 meteorology & atmospheric sciences, Infrared, Mineralogy, Astronomy and Astrophysics, Context (language use), Pyroxene, Mars Exploration Program, engineering.material, 01 natural sciences, Impact crater, Space and Planetary Science, 0103 physical sciences, engineering, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

We investigated the area to the northwest of the Isidis impact basin (hereby referred to as “NW Isidis”) using thermal infrared emission datasets to characterize and quantify bulk surface mineralogy throughout this region. This area is home to Jezero crater and the watershed associated with its two deltaic deposits in addition to NE Syrtis and the strong and diverse visible/near-infrared spectral signatures observed in well-exposed stratigraphic sections. The spectral signatures throughout this region show a diversity of primary and secondary surface mineralogies, including olivine, pyroxene, smectite clays, sulfates, and carbonates. While previous thermal infrared investigations have sought to characterize individual mineral groups within this region, none have systematically assessed bulk surface mineralogy and related these observations to visible/near-infrared studies. We utilize an iterative spectral unmixing method to statistically evaluate our linear thermal infrared spectral unmixing models to derive surface mineralogy. All relevant primary and secondary phases identified in visible/near-infrared studies are included in the unmixing models and their modeled spectral contributions are discussed in detail. While the stratigraphy and compositional diversity observed in visible/near-infrared spectra are much better exposed and more diverse than most other regions of Mars, our thermal infrared analyses suggest the dominance of basaltic compositions with less observed variability in the amount and diversity of alteration phases. These results help to constrain the mineralogical context of these previously reported visible/near-infrared spectral identifications. The results are also discussed in the context of future in situ investigations, as the NW Isidis region has long been promoted as a region of paleoenvironmental interest on Mars.

Published

2018

14. Comparison of the mineral composition of the sediment found in two Mars dunefields: Ogygis Undae and Gale crater – three distinct endmembers identified

Author

R. K. Hayward, Christopher S. Edwards, Caitlin Ahrens, Heather Charles, and Timothy N. Titus

Subjects

Thermal Emission Spectrometer, 010504 meteorology & atmospheric sciences, Lithology, Mineralogy, Pyroxene, Mars Exploration Program, Feldspar, 01 natural sciences, Geophysics, Space and Planetary Science, Geochemistry and Petrology, visual_art, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), visual_art.visual_art_medium, Aeolian processes, Thermal Emission Imaging System, Spatial variability, 010303 astronomy & astrophysics, Geomorphology, Geology, 0105 earth and related environmental sciences

Abstract

The composition of two dune fields, Ogygis Undae and the NE–SW trending dune field in Gale crater (the “Bagnold Dune Field” and “Western Dune Field”), were analyzed using thermal emission spectra from the Mars Global Surveyor (MGS) Thermal Emission Spectrometer (TES) and the Mars Odyssey Thermal Emission Imaging System (THEMIS). The Gale crater dune field was used as a baseline as other orbital compositional analyses have been conducted, and in situ sampling results will soon be available. Results from unmixing thermal emission spectra showed a spatial variation between feldspar mineral abundances and pyroxene mineral abundances in Ogygis Undae. Other datasets, including nighttime thermal inertia values, also showed variation throughout the dune field. One explanation proposed for this variation is a bimodal distribution of two sand populations. This distribution is seen in some terrestrial dune fields. The two dune fields varied in both mineral types present and in uniformity of composition. These differences point to different source lithologies and different distances travelled from source material. Examining these differences further will allow for a greater understanding of aeolian processes on Mars.

Published

2017

15. Comparing orbiter and rover image-based mapping of an ancient sedimentary environment, Aeolis Palus, Gale crater, Mars

Author

Abigail A. Fraeman, Dawn Y. Sumner, Christopher S. Edwards, Melissa S. Rice, S. R. Jacob, L. Le Deit, Kenneth S. Edgett, Kevin W. Lewis, Fred Calef, David M. Rubin, John P. Grotzinger, Rebecca M. E. Williams, Sanjeev Gupta, Lauren A. Edgar, Kenneth H. Williford, K. M. Stack, and Science and Technology Facilities Council (STFC)

Subjects

SELECTION, 010504 meteorology & atmospheric sciences, Mars, surface, Outcrop, LANDING SITE, Mars, 0404 Geophysics, Astronomy & Astrophysics, 01 natural sciences, Astrobiology, law.invention, Orbiter, law, 0103 physical sciences, 0402 Geochemistry, GEOLOGY, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, geography, Science & Technology, geography.geographical_feature_category, MINERALOGY, ORIGIN, Bedrock, Mars landing, Astronomy and Astrophysics, SCIENCE LABORATORY MISSION, Geophysics, Mars Exploration Program, Geologic map, Mars Hand Lens Imager, EVOLUTION, 0201 Astronomical And Space Sciences, Space and Planetary Science, Physical Sciences, Facies, Geological processes, Geology

Abstract

This study provides the first systematic comparison of orbital facies maps with detailed ground-based geology observations from the Mars Science Laboratory (MSL) Curiosity rover to examine the validity of geologic interpretations derived from orbital image data. Orbital facies maps were constructed for the Darwin, Cooperstown, and Kimberley waypoints visited by the Curiosity rover using High Resolution Imaging Science Experiment (HiRISE) images. These maps, which represent the most detailed orbital analysis of these areas to date, were compared with rover image-based geologic maps and stratigraphic columns derived from Curiosity's Mast Camera (Mastcam) and Mars Hand Lens Imager (MAHLI). Results show that bedrock outcrops can generally be distinguished from unconsolidated surficial deposits in high-resolution orbital images and that orbital facies mapping can be used to recognize geologic contacts between well-exposed bedrock units. However, process-based interpretations derived from orbital image mapping are difficult to infer without known regional context or observable paleogeomorphic indicators, and layer-cake models of stratigraphy derived from orbital maps oversimplify depositional relationships as revealed from a rover perspective. This study also shows that fine-scale orbital image-based mapping of current and future Mars landing sites is essential for optimizing the efficiency and science return of rover surface operations.

Published

2016

16. The stratigraphy and evolution of lower Mount Sharp from spectral, morphological, and thermophysical orbital data sets

Author

Daven P. Quinn, Ralph E. Milliken, Christopher S. Edwards, Melissa S. Rice, John P. Grotzinger, Raymond E. Arvidson, Bethany L. Ehlmann, and Abigail A. Fraeman

Subjects

geography, geography.geographical_feature_category, Spectral signature, 010504 meteorology & atmospheric sciences, Mineralogy, Geologic map, 01 natural sciences, Texture (geology), Sedimentary depositional environment, Geophysics, Stratigraphy, Space and Planetary Science, Geochemistry and Petrology, Ridge, Group (stratigraphy), 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Period (geology), 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

We have developed a refined geologic map and stratigraphy for lower Mt. Sharp using coordinated analyses of new spectral, thermophysical, and morphologic orbital data products. The Mt. Sharp group consists of seven relatively planar units delineated by differences in texture, mineralogy, and thermophysical properties. These units are (1-3) three spatially adjacent units in the Murray formation which contain a variety of secondary phases and are distinguishable by thermal inertia and albedo differences, (4) a phyllosilicate-bearing unit, (5) a hematite-capped ridge unit, (6) a unit associated with material having a strongly sloped spectral signature at visible-near infrared wavelengths, and (7) a layered sulfate unit. The Siccar Point group consists of the Stimson formation and two additional units that unconformably overlie the Mt. Sharp group. All Siccar Point group units are distinguished by higher thermal inertia values and record a period of substantial deposition and exhumation that followed the deposition and exhumation of the Mt. Sharp group. Several spatially extensive silica deposits associated with veins and fractures show late stage silica enrichment within lower Mt. Sharp was pervasive. At least two laterally extensive hematitic deposits are present at different stratigraphic intervals, and both are geometrically conformable with lower Mt. Sharp strata. The occurrence of hematite at multiple stratigraphic horizons suggests redox interfaces were widespread in space and/or in time, and future measurements by the Mars Science Laboratory Curiosity rover will provide further insights into the depositional settings of these and other mineral phases.

Published

2016

17. The geologic history of Margaritifer basin, Mars

Author

Christopher S. Edwards, Mark R. Salvatore, Philip R. Christensen, and Michael D. Kraft

Subjects

Martian, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Fluvial, Mars Exploration Program, Structural basin, 01 natural sciences, Paleontology, Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Sedimentary rock, Chaos terrain, 010303 astronomy & astrophysics, Geomorphology, Channel (geography), Geology, 0105 earth and related environmental sciences

Abstract

In this study, we investigate the fluvial, sedimentary, and volcanic history of Margaritifer basin and the Uzboi-Ladon-Morava outflow channel system. This network of valleys and basins spans more than 8000 km in length, linking the fluvially dissected southern highlands and Argyre basin with the northern lowlands via Ares Vallis. Compositionally, thermophysically, and morphologically distinct geologic units are identified and are used to place critical relative stratigraphic constraints on the timing of geologic processes in Margaritifer basin. Our analyses show that fluvial activity was separated in time by significant episodes of geologic activity, including the widespread volcanic resurfacing of Margaritifer basin and the formation of chaos terrain. The most recent fluvial activity within Margaritifer basin appears to terminate at a region of chaos terrain, suggesting possible communication between surface and subsurface water reservoirs. We conclude with a discussion of the implications of these observations on our current knowledge of Martian hydrologic evolution in this important region.

Published

2016

18. MGS-TES Spectra Suggest a Basaltic Component in the Regolith of Phobos

Author

D. McDougall, Christopher D. K. Herd, Christopher S. Edwards, Alexander Kling, Joshua L. Bandfield, K. A. Shirley, Timothy D. Glotch, and Mehmet Yesiltas

Subjects

Basalt, spectroscopy, 010504 meteorology & atmospheric sciences, Component (thermodynamics), MGS-TES, Tagish Lake, Mineralogy, 01 natural sciences, Regolith, Spectral line, Phobos, Geophysics, Space and Planetary Science, Geochemistry and Petrology, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Spectroscopy, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Plain Language Summary The origins of the Martian moons Phobos and Deimos have been the subjects of considerable debate. Visible and near-infrared spectra of these bodies are dark and nearly featureless, with red slopes of varying degrees. These spectra are generally consistent with those of carbonaceous asteroids, leading to the hypothesis that Phobos and Deimos are captured carbonaceous asteroids. The shapes and inclinations of the orbits of Phobos and Deimos present problems for the asteroid capture hypothesis. This had led researchers to suggest that Phobos and Deimos coaccreted with Mars or that they are the result of an impact with Mars or in the Mars vicinity. In this work, we reexamine Mars Global Surveyor Thermal Emission Spectrometer (MGS-TES) data of Phobos and compare spectra of the Phobos surface to mid-IR spectra of the ungrouped C2 meteorite Tagish Lake (a suggested analog for D-class asteroids) and particulate basalt and phyllosilicate samples (mixed with carbon black to reduce their visible albedos) acquired in a simulated airless body environment. We find that Tagish Lake is a poor mid-IR spectral analog to Phobos and that major spectral features in the Phobos spectrum are best matched by a silicate transparency feature similar to that found for finely particulate basalt. Other features in the spectrum are likely best explained by a phyllosilicate component. We suggest that these results indicate that at a portion of the Phobos surface regolith is derived from the Martian crust. The Martian moons Phobos and Deimos have been suggested to be captured asteroids based on the similarities between the dark, red, nearly featureless visible and near-infrared spectra of these bodies and carbonaceous asteroids. However, the capture hypothesis suffers from difficulties associated with the shapes and inclinations of the moons' orbits. Alternatively, Phobos and Deimos have been suggested to originate from an impact with, or in the vicinity of, Mars. In this work, we examine midinfrared spectra of Phobos and compare them with spectra of different materials acquired in the laboratory under simulated airless body conditions. We find that the mid-IR spectra of Phobos are most consistent with the presence of a basaltic component, perhaps with admixed phyllosilicates. As the Martian crust is mostly composed of basaltic rocks, we suggest that Phobos (and likely Deimos) resulted from an impact with Mars. RIS4E node of NASA's Solar System Exploration Research Virtual Institute This work was supported by the RIS4E node (T. D. Glotch, PI) of NASA's Solar System Exploration Research Virtual Institute. TES footprint polygons and spectra and all laboratory spectra discussed in the text will be permanently archived at the Stony Brook University Academic Commons archive (https://commons.library.stonybrook.edu/). The authors gratefully acknowledge the detailed and constructive reviews of Drs. Matthew Izawa and Abigail Fraeman, whose reviews improved the content and clarity of the manuscript. The authors also thank Paul Lucey (U. Hawaii) for helpful discussions about the visible albedo of the lunar maria and Joel Hurowitz for providing the Columbia River basalt sample.

Published

2018

19. The Thermophysical Properties of the Bagnold Dunes, Mars: Ground-truthing Orbital Data

Author

Robin L. Fergason, Christopher S. Edwards, M. D. Smith, Sylvain Piqueux, Kevin M. Lewis, L. E. Sacks, Kristen A. Bennett, Victoria E. Hamilton, Kenneth E. Herkenhoff, and Ashwin R. Vasavada

Subjects

Earth and Planetary Astrophysics (astro-ph.EP), Materials science, 010504 meteorology & atmospheric sciences, Scale (ratio), Mineralogy, FOS: Physical sciences, Mars Exploration Program, Mars Hand Lens Imager, 01 natural sciences, Geophysics, Space and Planetary Science, Geochemistry and Petrology, 0103 physical sciences, Thermal, Earth and Planetary Sciences (miscellaneous), Particle, Thermal Emission Imaging System, Particle size, Layering, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Astrophysics - Earth and Planetary Astrophysics

Abstract

In this work, we compare the thermophysical properties and particle sizes derived from the Mars Science Laboratory (MSL) rover's Ground Temperature Sensor (GTS) of the Bagnold dunes, specifically Namib dune, to those derived orbitally from Thermal Emission Imaging System (THEMIS), ultimately linking these measurements to ground-truth particle sizes determined from Mars Hand Lens Imager (MAHLI) images. In general, we find that all three datasets report consistent particle sizes for the Bagnold dunes (~110-350 microns, and are within measurement and model uncertainties), indicating that particle sizes of homogeneous materials determined from orbit are reliable. Furthermore, we examine the effects of two physical characteristics that could influence the modeled thermal inertia and particle sizes, including: 1) fine-scale (cm-m scale) ripples, and 2) thin layering of indurated/armored materials. To first order, we find small scale ripples and thin (approximately centimeter scale) layers do not significantly affect the determination of bulk thermal inertia from orbital thermal data determined from a single nighttime temperature. Modeling of a layer of coarse or indurated material reveals that a thin layer (< ~5 mm; similar to what was observed by the Curiosity rover) would not significantly change the observed thermal properties of the surface and would be dominated by the properties of the underlying material. Thermal inertia and grain sizes of relatively homogeneous materials derived from nighttime orbital data should be considered as reliable, as long as there are not significant sub-pixel anisothermality effects (e.g. lateral mixing of multiple thermophysically distinct materials)., submitted to the Journal of Geophysical Research: Planets

Published

2017

20. Mineralogy of the Martian Surface

Author

Christopher S. Edwards and Bethany L. Ehlmann

Subjects

Basalt, Amazonian, Earth science, Geochemistry, Noachian, Astronomy and Astrophysics, Crust, Mars Exploration Program, engineering.material, Space and Planetary Science, Martian surface, Earth and Planetary Sciences (miscellaneous), engineering, Plagioclase, Hesperian, Geology

Abstract

The past fifteen years of orbital infrared spectroscopy and in situ exploration have led to a new understanding of the composition and history of Mars. Globally, Mars has a basaltic upper crust with regionally variable quantities of plagioclase, pyroxene, and olivine associated with distinctive terrains. Enrichments in olivine (>20%) are found around the largest basins and within late Noachian–early Hesperian lavas. Alkali volcanics are also locally present, pointing to regional differences in igneous processes. Many materials from ancient Mars bear the mineralogic fingerprints of interaction with water. Clay minerals, found in exposures of Noachian crust across the globe, preserve widespread evidence for early weathering, hydrothermal, and diagenetic aqueous environments. Noachian and Hesperian sediments include paleolake deposits with clays, carbonates, sulfates, and chlorides that are more localized in extent. The late Hesperian to Amazonian mineralogic record of water is sparser, though sulfates and silica in some locations indicate local availability of ground and surface waters even in the most recent geologic epoch.

Published

2014

21. The formation of infilled craters on Mars: Evidence for widespread impact induced decompression of the early martian mantle?

Author

Philip R. Christensen, Christopher S. Edwards, Joshua L. Bandfield, and A. D. Rogers

Subjects

Martian, geography, geography.geographical_feature_category, Geochemistry, Astronomy and Astrophysics, Volcanism, Mars Exploration Program, Mantle (geology), Astrobiology, Volcano, Impact crater, Space and Planetary Science, Lithosphere, Terrestrial planet, Geology

Abstract

Flat-floored craters have long been recognized on Mars with early work hypothesizing a sedimentary origin. More recently, high-resolution thermal inertia measurements show that these craters contain some of the rockiest materials on the planet, inconsistent with poorly consolidated sedimentary materials. In this study, the distribution, physical properties (morphology and thermal inertia), and composition of these craters are thoroughly investigated over the entire planet. The majority of the ∼2800 rocky crater floors identified are concentrated in the low albedo (0.1–0.17), cratered southern highlands. These craters were infilled at ∼3.5 Ga and are associated with the highest thermal inertia values and some of the most mafic materials identified on the planet. Although several processes may have led to the formation of the crater floors, the most likely scenario is volcanic infilling through fractures created by the impact event. The primitive magma source directly results from decompression melting of the martian mantle by the removal of the crustal material excavated by the impactor. Volcanic infilling of craters by decompression melting appears to only have occurred in early martian history when the lithosphere was still relatively thin and the thermal gradient was high. This process was widespread and responsible for the eruption of significant volumes of primitive material, inside and likely outside of craters. Impact induced decompression melting of the martian mantle accounts for the unusual infilling of martian craters and is a widespread planetary process that has gone previously undocumented.

Published

2014

22. Material ejection by the cold jets and temperature evolution of the south seasonal polar cap of Mars from THEMIS/CRISM observations and implications for surface properties

Author

Cedric Pilorget, Christopher S. Edwards, François Forget, Ehouarn Millour, and Bethany L. Ehlmann

Subjects

010504 meteorology & atmospheric sciences, Mars Exploration Program, Atmospheric sciences, 01 natural sciences, CRISM, Geophysics, 13. Climate action, Space and Planetary Science, Geochemistry and Petrology, Defrosting, 0103 physical sciences, Thermal, Earth and Planetary Sciences (miscellaneous), Polar, Thermal Emission Imaging System, Sublimation (phase transition), Longitude, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

As the seasonal CO_2 ice polar caps of Mars retreat during spring, dark spots appear on the ice in some specific regions. These features are thought to result from basal sublimation of the transparent CO_2 ice followed by ejection of regolith-type material, which then covers the ice. We have used Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) reflectance data, Thermal Emission Imaging System (THEMIS) visible images, and THEMIS-derived temperature retrievals along with a thermal numerical model to constrain the physical and compositional characteristics of the seasonal cap for several areas exhibiting dark spots at both high spatial and temporal resolutions. Data analysis suggests an active period of material ejection (before solar longitude (Ls) 200), accumulation around the ejection points, and spreading of part of the ejected material over the whole area, followed by a period where no significant amount of material is ejected, followed by complete defrosting (≈ Ls 245). Dark material thickness on top of the CO_2 ice is estimated to range from a few hundreds of microns to a few millimeters in the warmest spots, based on numerical modeling combined with the observed temperature evolution. The nature of the venting process and the amount of material that is moved lead to the conclusion that it could have an important impact on the surface physical properties.

Published

2013

23. A new method for the semiquantitative determination of major rock-forming minerals with thermal infrared multispectral data: Application to THEMIS infrared data

Author

Christopher S. Edwards, Philip R. Christensen, Steven W. Ruff, Long Xiao, and Jun Huang

Subjects

Mineral, Infrared, Multispectral image, Mineralogy, Hyperspectral imaging, Mars Exploration Program, Feldspar, Petrography, Geophysics, Space and Planetary Science, Geochemistry and Petrology, visual_art, Earth and Planetary Sciences (miscellaneous), visual_art.visual_art_medium, Thermal Emission Imaging System, Geology, Remote sensing

Abstract

[1] We have developed a new method (least residual iterative spectral mixture analysis (LRISMA)) to semiquantitatively determine major rock-forming minerals (feldspar, pyroxene, olivine, high-silica phases, and quartz) with multispectral thermal infrared data. Sublibraries of minerals are generated from a master library of minerals based on prior knowledge to produce a suite of realistic mineral end-member combinations to fit the target spectra. Mineral abundances that correspond to the least root-mean-square errors (best fit) generally agree best with previous petrographic studies of laboratory-measured rock samples and thermal infrared hyperspectral analysis of materials on the surface of Mars, given the greatly reduced spectral range and resolution of Thermal Emission Imaging System (THEMIS) spectra. The accuracy and reproducibility of LRISMA is ~4–16% and ~5–20%, respectively, while the accuracy of petrographic and previous hyperspectral studies is ~5–15%. LRISMA can be applied to semiquantitatively refine the bulk surface mineralogy of small-scale (~1 km2) geologic features with high-quality THEMIS spectral data (high surface temperature: >260 K, low atmospheric opacity: total ice

Published

2013

24. Searching at the right time of day: Evidence for aqueous minerals in Columbus crater with TES and THEMIS data

Author

Melissa D. Lane, A. M. Baldridge, and Christopher S. Edwards

Subjects

Martian, Opacity, Diurnal temperature variation, Mars Exploration Program, Astrobiology, CRISM, Geophysics, Time of day, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Thermal Emission Imaging System, Geology

Abstract

The primary objective of the Thermal Emission Imaging System (THEMIS) experiment, which has been in orbit at Mars since early 2002, is to identify minerals associated with hydrothermal and subaqueous environments. Data from THEMIS have supported the presence of clays, silica-rich deposits, and chlorides but has not before provided definitive evidence for the presence of sulfates. This is an especially puzzling result given that sulfates have been extensively identified with other instruments at Mars. If present, sufficiently exposed, and in high enough abundances, such minerals should be detectable in orbital thermal infrared spectra at the resolution of THEMIS. The extended mission proposal for THEMIS on Mars Odyssey suggests that the detection of all minerals may be enhanced by observing at an earlier time of day and thus at warmer temperatures. Therefore, in 2009, Odyssey moved to an earlier orbit time. Here, we examine THEMIS data collected when the earlier orbit time coincided with the Martian local (southern) late summer (Ls = 270) for Columbus crater where Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) data have detected a number of aqueous minerals. Some of the warmest THEMIS images show evidence for aqueous minerals, although not in the same locations where CRISM finds the highest concentrations. Several factors contribute to this result, including differences in the diurnal temperature curve and levels of induration and particle size. For THEMIS, earlier time-of-day and proper seasonal observations combine to provide warm surface temperatures and ideal low atmospheric opacity that significantly increases the ability to definitively identify low spectral contrast aqueous minerals at the surface of Mars.

Published

2013

25. The dual nature of the martian crust: Young lavas and old clastic materials

Author

Christopher S. Edwards, Joshua L. Bandfield, Brittany D. Brand, and David R. Montgomery

Subjects

Martian, Space and Planetary Science, Lava, Geochemistry, Pyroclastic rock, Hesperian, Astronomy and Astrophysics, Crust, Mars Exploration Program, Volcanism, Mantle (geology), Geology

Abstract

Visible and thermal infrared spacecraft datasets are used to gain insight into the nature of the surface materials and upper martian crust, revealing a distinct transition in the physical properties of martian crustal materials that occurred during the Hesperian era. Contrary to a prevailing view of the martian crust as primarily composed of lava flows, we find that most older regions of Mars have morphological and thermophysical properties consistent with poorly consolidated fine-particulate materials that may have a volcaniclastic origin. By contrast, younger surfaces contain blocky materials and thermophysical properties consistent with effusive lava flows. Explosive volcanism is likely to have been dominant on early Mars and these findings have implications for the evolution of the volatile content of the crust and mantle and subsequent development of the surface morphology. This dual nature of the crust appears to be a defining characteristic of martian history.

Published

2013

26. The role of aqueous alteration in the formation of martian soils

Author

Joshua L. Bandfield, Christopher S. Edwards, and A. Deanne Rogers

Subjects

Basalt, Martian, Olivine, Lithology, Geochemistry, Astronomy and Astrophysics, Weathering, Mars Exploration Program, engineering.material, Astrobiology, Space and Planetary Science, Soil water, engineering, Dissolution, Geology

Abstract

Martian equatorial dark regions are dominated by unweathered materials and it has often been assumed that they have not been significantly altered from their source lithology. The suite of minerals present is consistent with a basaltic composition and there has been no need to invoke additional processes to explain the origin of these compositions. We have begun to question this result based on detailed observations using a variety of datasets. Locally derived dark soils have a mineralogy distinct from that of adjacent rocky surfaces; most notably a lower olivine content. This pattern is common for many surfaces across the planet. Previous work using detailed measurements acquired within the Gusev Plains has shown that olivine dissolution via acidic weathering may explain chemical trends observed between rock rinds and interiors. Mineralogical trends obtained from rocks and soils within the Gusev Plains are more prominent than the elemental trends and support previous results that indicate that dissolution of olivine has occurred. However, clear differences are also present in elemental abundances that indicate a variety of inputs and processes are likely responsible for the formation of martian dark soils. Despite the potential complexity of source materials and processes, it appears that most martian dark regions have likely experienced aqueous alteration and chemical weathering appears to be closely linked to the mechanical breakdown of materials. Regardless of the responsible mechanism, there appears to be a general, though not perfect, correlation between elevated olivine abundance and high-thermal inertia surfaces on Mars.

Published

2011

27. Derivation of martian surface slope characteristics from directional thermal infrared radiometry

Author

Christopher S. Edwards and Joshua L. Bandfield

Subjects

Thermal Emission Spectrometer, Mineralogy, Astronomy and Astrophysics, Viewing angle, Latitude, Azimuth, Photometry (optics), Space and Planetary Science, Martian surface, Surface roughness, Radiometry, Astrophysics::Earth and Planetary Astrophysics, Geology, Remote sensing

Abstract

Directional thermal infrared measurements of the martian surface is one of a variety of methods that may be used to characterize surface roughness and slopes at scales smaller than can be obtained by orbital imagery. Thermal Emission Spectrometer (TES) emission phase function (EPF) observations show distinct apparent temperature variations with azimuth and emission angle that are consistent with the presence of warm, sunlit and cool, shaded slopes at typically ∼0.1 m scales. A surface model of a Gaussian distribution of azimuth independent slopes (described by θ -bar) is combined with a thermal model to predict surface temperature from each viewing angle and azimuth of the TES EPF observation. The models can be used to predict surface slopes using the difference in measured apparent temperature from 2 separate 60–70° emission angle observations taken ∼180° in azimuth relative to each other. Most martian surfaces are consistent with low to moderate slope distributions. The slope distributions display distinct correlations with latitude, longitude, and albedo. Exceptionally smooth surfaces are located at lower latitudes in both the southern highlands as well as in high albedo dusty terrains. High slopes are associated with southern high-latitude patterned ground and north polar sand dunes. There is little apparent correlation between high resolution imagery and the derived θ -bar, with exceptions such as duneforms. This method can be used to characterize potential landing sites by assuming fractal scaling behavior to meter scales. More precisely targeted thermal infrared observations from other spacecraft instruments are capable of significantly reducing uncertainty as well as reducing measurement spot size from 10s of kilometers to sub-kilometer scales.

Published

2008

28. Mosaicking of global planetary image datasets: 1. Techniques and data processing for Thermal Emission Imaging System (THEMIS) multi-spectral data

Author

Christopher S. Edwards, Noel Gorelick, K. Murray, K. J. Nowicki, Jonathon Hill, and Philip R. Christensen

Subjects

Atmospheric Science, Data processing, Ecology, Pixel, Multispectral image, Normalization (image processing), Paleontology, Soil Science, Image registration, Forestry, Context (language use), Mars Exploration Program, Aquatic Science, Oceanography, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Thermal Emission Imaging System, Geology, Earth-Surface Processes, Water Science and Technology, Remote sensing

Abstract

[1] The mosaicking of global planetary data sets allows for the examination of local, regional, and global scale processes on all planetary bodies. Processing techniques that allow us and other users to crate mosaics of tens of thousands of images are documented along with the associated errors introduced by each image-processing algorithm. These techniques (e.g., non-uniformity correction, running contrast stretches, line and row correlated noise removal, and random noise removal) were originally developed for the 2001 Mars Odyssey Thermal Emission Imaging System (THEMIS) infrared multispectral imager data but can be adapted and applied to other data sets by the alteration of input parameters. The techniques for mosaicking planetary image data sets (e.g., image registration, blending, and normalization) are also presented along with the generation of qualitative and quantitative products. These techniques are then applied to generate THEMIS daytime and nighttime infrared, Viking, Context Imager (CTX), and Mars Orbiter Camera (MOC) visible mosaics using a variety of input and output types at a variety of scales. By creating mosaics of the same area using different data sets such as those that illustrate compositional diversity, thermophysical properties, or small-scale morphology, it is possible to view the surface of the planet and geologic problems through many different perspectives. In addition to the techniques used to create large-scale seamless mosaics, we also present the THEMIS daytime and nighttime relative temperature global mosaics, which are the highest resolution (100m/pixel) global scale data sets available for Mars to date.

Published

2011

29. Mosaicking of global planetary image datasets: 2. Modeling of wind streak thicknesses observed in Thermal Emission Imaging System (THEMIS) daytime and nighttime infrared data

Author

Christopher S. Edwards, Jonathon Hill, and Philip R. Christensen

Subjects

Atmospheric Science, Daytime, Ecology, Global wind patterns, Streak, Paleontology, Soil Science, Forestry, Context (language use), Geophysics, Mars Exploration Program, Aquatic Science, Wind direction, Oceanography, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Aeolian processes, Thermal Emission Imaging System, Geology, Earth-Surface Processes, Water Science and Technology, Remote sensing

Abstract

[1] Large-scale, seamless global mosaics, such as the Thermal Emission Imaging System (THEMIS) mosaics, can be used to assess regional- and local-scale relative thermophysical properties, morphology, geology, and other compositional investigations. In this paper we use the THEMIS global mosaics as reconnaissance tools to assess the relative thermophysical properties of materials and target a specific location to examine with a quantitative thermal model. This example highlights the utility of these new data sets through an investigation of the thermophysical properties of wind streaks near the Syrtis Major and Uranius Mons regions. In this study, we quantitatively model depositional wind streak thicknesses near Syrtis Major for a thermophysically homogeneous substrate and a top layer consistent with air fall dust. Using this two layer thermal model, we calculate that wind streaks near Syrtis Major are likely 30–200 μm thick, depending on the top layer thermal inertia. Given predicted dust deposition and removal rates, we calculate that these wind streaks likely formed in

Published

2011

30. Global distribution of bedrock exposures on Mars using THEMIS high-resolution thermal inertia

Author

Christopher S. Edwards, Joshua L. Bandfield, Robin L. Fergason, and Philip R. Christensen

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Bedrock, Paleontology, Soil Science, Mineralogy, Forestry, Mars Exploration Program, Mass wasting, Aquatic Science, Albedo, Oceanography, Permafrost, Regolith, Geophysics, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Thermal Emission Imaging System, Geology, Earth-Surface Processes, Water Science and Technology

Abstract

[1] We investigate high thermal inertia surfaces using the Mars Odyssey Thermal Emission Imaging System (THEMIS) nighttime temperature images (100 m/pixel spatial sampling). For this study, we interpret any pixel in a THEMIS image with a thermal inertia over 1200 J m -2 K -1 s -1/2 as "bedrock" which represents either in situ rock exposures or rock-dominated surfaces. Three distinct morphologies, ranked from most to least common, are associated with these high thermal inertia surfaces: (1) valley and crater walls associated with mass wasting and high surface slope angles; (2) floors of craters with diameters >25 km and containing melt or volcanics associated with larger, high-energy impacts; and (3) intercrater surfaces with compositions significantly more mafic than the surrounding regolith. In general, bedrock instances on Mars occur as small exposures (less than several square kilometers) situated in lower-albedo ( 350 J m -2 K -1 s -1/2 ), and relatively dust-free (dust cover index

Published

2009

31. Evidence for extensive olivine-rich basalt bedrock outcrops in Ganges and Eos chasmas, Mars

Author

Christopher S. Edwards, Philip R. Christensen, and Victoria E. Hamilton

Subjects

Basalt, Atmospheric Science, Thermal Emission Spectrometer, Ecology, Outcrop, Geochemistry, Paleontology, Soil Science, Forestry, Geophysics, Aquatic Science, Oceanography, Space and Planetary Science, Geochemistry and Petrology, Martian surface, Mars Orbiter Laser Altimeter, Earth and Planetary Sciences (miscellaneous), Flood basalt, Thermal Emission Imaging System, Geology, Earth-Surface Processes, Water Science and Technology, Tharsis

Abstract

[1] Several localized outcrops of olivine-enriched bedrock have been previously identified in the Ganges and Eos Chasma area on the eastern end of Valles Marineris with the Thermal Emission Imaging System multispectral images. These outcrops form a layer in the walls of Ganges Chasma and appear to be the remnants of a once continuous unit, which was mapped over ∼100 km. In this study we further characterize the composition (forsterite content of ∼0.68), olivine abundance (10 to >15%), thermal inertia (>600 JK−1 m−2 s−1/2, consistent with in-place rocky material), vertical dimension (∼60 to ∼220 m), extent (>1100 km laterally), volume (∼9.9 × 104 km3), dip (∼0.013°NE), and continuity of this layer utilizing Thermal Emission Spectrometer hyperspectral, Thermal Emission Imaging System multispectral, and Mars Orbiter Laser Altimeter elevation data. Morphologic data from high-resolution imagery display a relatively unmantled, rough, and pitted surface associated with the olivine-enriched material, consistent with thermal inertia data. Four possibilities for the origin of the olivine-enriched unit are (1) volcanism associated with tectonic rifting of the Valles Marineris system, (2) a volcaniclastic flow deposit, (3) an intrusive mafic sill, or (4) a discrete episode in Martian history during which flood lavas were erupted onto the surface. The most likely origin is an eruptive event consisting of compositionally uniform flood lavas originating from a primitive mantle source region, possibly associated with the initiation of Tharsis volcanism. This unit is one of the largest continuous compositional units found on Mars and is strikingly similar to other olivine-enriched deposits identified in previous studies where compositional, morphologic, and thermophysical similarities are observed. These similarities may indicate that there was a period in early Martian history, where compositionally uniform and extensive olivine-enriched flood basalts were erupted on the Martian surface.

Published

2008

32. Distribution of the ices exposed near the south pole of Mars using Thermal Emission Imaging System (THEMIS) temperature measurements

Author

Christopher S. Edwards, Sylvain Piqueux, and Philip R. Christensen

Subjects

Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Water cycle, Earth-Surface Processes, Water Science and Technology, geography, geography.geographical_feature_category, Ecology, Paleontology, Forestry, Mars Exploration Program, Geophysics, Arctic ice pack, CRISM, Space and Planetary Science, Sea ice thickness, Thermal Emission Imaging System, Martian polar ice caps, Geology, Water vapor

Abstract

[1] Understanding the present and past water cycle on Mars requires an accurate knowledge of the distribution and amount of H2O available near the surface. In this article, we present a map of the distribution of the surface material exposed between 87°S and 70°S in the summer (e.g., CO2 and H2O ices, dust) based on temperature measurements made by Thermal Emission Imaging System (THEMIS). Our compositional map (100 m per pixel) is in good agreement with spectral mapping returned by Observatoire pour la mineralogie, l'Eau, la Glace et l'activite (OMEGA) and Compact Reconnaissance Imaging Spectrometer for Mars (CRISM). Exposed water ice covers a total surface area of approximately 40,000 km2. A large fraction of the water ice is exposed at the periphery of the CO2 cap. An approximately 25,000-km2 large patch centered at 83.5°S and 345°E is discovered and represents the largest exposure of water ice in the southern hemisphere. It is not located on the south polar layered deposits but on the surrounding mantled terrains. THEMIS VIS, MOC and HiRISE images indicate that the surface roughness of exposed water ice terrains is typically lower than that of the surrounding dust. Polygonal patterns are observed on the water ice but not exclusively. There is a strong correlation between the surface albedo, the composition of the exposed material, and the timing of the initial seasonal CO2 frost deposition and final removal. These exposed water ice outcrops are not stable in the present environment and lose a vertical layer of tens to hundreds of micrometer a year to the atmosphere. The spike of water vapor above the south pole during the southern summer occurs while the water ice is still covered by a layer of seasonal CO2 frost, indicating that the sublimation of the exposed water ice is not the main contributor of vapor for the southern atmosphere. As water ice is not stable, it may indicate the past location of part of the CO2 perennial cap that has been eroded.

Published

2008