Bruce Cantor | Malin Space Science Systems | Dust Storm Activity at Mars 2020 Rover Candidate Landing Locations from Mars Orbiter Camera and Mars Color Imager data |
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David Hinson | SETI Institute | Surface Pressure Predictions from Data Assimilation with Independent Validation | ||||
Gareth Morgan | Smithsonian Institute | Constraining the Surface Properties of Mars 2020 Landing Sites from Radar Data | ||||
Robin Fergason | US Geological Survey | Landing Site Surface and Subsurface Thermal Property Characterization for the Mars 2020 Mission | ||||
J. Barnes | Oregon State University | Landing site characterization for the Mars 2020 Rover Mission | ||||
B. Bills | Jet Propulsion Laboratory | Mars gravity analysis in support of Mars 2020 rover mission entry, descent, and landing | ||||
R. Kirk | US Geological Survey | Digital Elevation Models for Mars 2020 from Context Images | ||||
S. Rafkin | Southwest Research Institute | Initial Atmospheric Characterization of the Mars 2020 Landing Site | ||||
B.L. Ehlmann | California Institute of Technology | Land-On Science at the Nili Fossae Carbonate Plains: Aqueous Alterations of Ultramafic Rocks and Clay-Carbonate Stratigraphy |
Presentations
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B. Ehlmann | California Institute of Technology | Jezero Crater Basin Stratigraphy, Sedimentology, and Mineralogy | Jezero Crater Delta: Reading the Geochemical Record of Clay-Carbonate Sedimentation – Ehlmann et al., 2014, presented at 1st Landing Site Workshop for Mars 2020 Rover | ||||||||||||||||
C.M Weitz | Planetary Science Institute | A Proposed Mars Landing Site West of Ladon Basin: Source-To-Sink Access to Ancient Crustal and Clay-Bearing Sedimentary Rocks | Sedimentary deposits associated with small upland basins around Landon Basin – Weitz et al, 2013, presented at LPSC, Ab. 2081 | ||||||||||||||||
C.M Weitz | Planetary Science Institute | A Proposed Mars Landing Site in Aram Chaos: Analyzing Possible Lacustrine Sediments | |||||||||||||||||
E. Noe Dobrea | Planetary Science Institute | Hydrothermal Deposits in NW Hellas as Landing Sites for Future Missions | Hydrothermal Alteration in the NW Hellas Region – Dobrea & Swayze, 2012, presented at First Landing Site Workshop: Possible Joint Rover 2018 Landing Sites | ||||||||||||
W. Farrand | Space Science Institute | Exploration of Phyllosilicate-Bearing Terrains South of Mawrth Vallis |
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J. Michalski | Planetary Science Institute | Carbonates and Hydrothermal Phyllosilicates Exhumed from Deep in the Martian Crust: A High Priority Target for Future Mars Exploration |
Presentations
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C.M Weitz | Planetary Science Institute | Investigation of Layered Sediments and Clays at Proposed Landing Sites in Ladon Valles |
Presentations
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S.W. Bougher | Univ. of Michigan | Coupled MGCM-MTGCM Mars Thermosphere Simulations and Resulting Data Products in Support of the MAVEN Mission | ||||
S.L. England | Univ. of California, Berkeley | MAVEN Critical Data Products from MGS MAG/ER | On the nature of the variability of the Martian thermospheric mass density: Results from electron reflectometry with Mars Global Surveyor – England, 2012, J. Geophys. Res. 117 | |||
P. Withers | Boston Univ. | Empirical thermospheric variability observed by past aerobraking missions and radio science occultation experiments |
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J. Bandfield | Univ. of Washington | Characterization of Altered and Evolved Lithologies in Antoniadi Crater/Syrtis Major, Mars: Assessment of Potential Future Landing Sites | Felsic and Altered Mineral Suite in Antoniadi Crater, Mars as a Future Rover Landing Site – Bandfield et al, 2011, presented at LPSC, Ab. 1671 | ||||||||||||
J. Bishop | SETI Institute | CRISM and HiRISE Investigation of Aqueous Materials at the Juventae Plateau in order to Identify and Characterize a New Landing Site with High Potential for Habitability and Preservation of Biosignatures |
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L. Crumpler | New Mexico Museum of Natural History | Mars Landing Sites in Phyllosilicate, Carbonate (?), and Ancient Crustal Terrains of Libya Montes. | Mars Landing Sites in Phyllosilicate, Carbonate, and Ancient Wet Noachian Terrains of Libya Montes, Crumpler et al, 2012, presented at LPSC, Ab. 1261 | ||||||||||||
J. Grotzinger | California Institute of Technology | Future Mars Landing Sites at Terby Crater and Melas Chasma | |||||||||||||
J.R. Michalski | Planetary Science Institute | Fe/Mg-Phyllosilicates, Al- Phyllosilicates, and Sulfates: a Complex Aqueous Environment for Future Mars Exploration and Sample Return |
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C. Weitz | Planetary Science Institute | Investigation of Diverse Mineralogies in a Proposed Future Mars Landing Site at Noctis Labyrinthus | |||||||||||||
R. Williams | Planetary Science Institute | Interdisciplinary Investigation of Melas Basin for future Mars Landers |
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J.L. Bandfield | Arizona State Univ. | TES and THEMIS surface mineralogy, dust cover, and emissivity for MSL landing site characterization |
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J.R. Barnes | Oregon State Univ. | Multiple-scale modeling of the near-surface environment for MSL surface operations |
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B. Cantor | Malin Space Science Systems | Dust storm activity at proposed MSL landing locations from Mars Orbiter Camera and Mars Color Imager data | MOC observations of the 2001 Mars planet-encircling dust storm – Cantor, 2007, Icarus 186 | ||||||||||||||||||||||||||||||||||||
Y. Cheng | Jet Propulsion Laboratory | High precision rock abundance and distribution mapping for MSL Landing Site selection | Toward improved landing precision on Mars – Wolf et al., 2011, presented at Aerospace Conference, IEEE, paper 1209 | ||||||||||||||||||||||||||||||||||||
P.R. Christensen | Arizona State Univ. | THEMIS-derived Thermal Inertia and Temperature Mosaics of the MSL Candidate Landing Sites |
Presentations
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D.P. Hinson | Carl Sagan Center SETI | Investigation of atmospheric density/temperature profiles for Entry, Descent, and Landing (EDL) of the Mars Science Laboratory (MSL) through data assimilation |
Presentations
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R. Kirk | U.S. Geological Survey, Flagstaff | High-Resolution Elevation Models for MSL from MRO CTX and HiRISE Images |
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T.Z. Martin | Jet Propulsion Laboratory | Compilation of Martian dust opacity mapping and statistics | |||||||||||||||||||||||||||||||||||||
F. Seelos | Johns Hopkins Universtiy / Applied Physics Laboratory | Mineralogical Mapping for MSL |
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M. Smith | Goddard Space Flight Center | Mars IR Dust Climatology | |||||||||||||||||||||||||||||||||||||
M. Smith | Goddard Space Flight Center | Atmospheric Temperature Characterization for MSL EDL | |||||||||||||||||||||||||||||||||||||
A. Toigo | Cornell Univ. | Atmospheric Modeling of Winds during MSL EDL | |||||||||||||||||||||||||||||||||||||
P. Withers | Boston Univ. | Spirit and Opportunity Atmospheric EDL Density/Temperature Profiles |
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P. Christensen | Arizona State Univ. | Surface slope characteristics from TES EPF observations | Mars Exploration Program 2007 Phoenix landing site selection and Characteristics – Arvidson et al, 2008, J. Geophys. Res. 113 | ||||||||||||||||||||
M.P. Golombek | Jet Propulsion Laboratory | Rock size-frequency distributions at potential Phoenix landing sites |
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R. Kirk | U.S. Geological Survey, Flagstaff | High resolution topographic mapping of candidate Phoenix landing sites |
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J. Rice | Arizona State Univ. | THEMIS systematic monitoring of the Phoenix landing site regions | |||||||||||||||||||||
M.P. Golombek | Jet Propulsion Laboratory | Boulder size-frequency distributions in the northern plains |
Presentations
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G.M. Keating | George Washington Univ. | Characterization of the Mars upper atmosphere in support of MRO and future missions from Mars Express (MEx) experiments | Initial Mars upper atmospheric structure results from the accelerometer science experiment aboard Mars Reconnaissance Orbiter – Keating et al., 2006, presented at AGU Fall Meeting, Ab. P33A-06 | ||||||||||||||||||||||||
M.C. Malin | Malin Space Science Systems | High resolution slope analysis using Digital Elevation Maps derived from Mars Orbiter Camera data | Introduction to special section on the Phoenix Mission: Landing Site Characterization Experiments, Mission Overviews, and Expected Science – Smith et al., 2008, J. Geophys. Res. 113 | ||||||||||||||||||||||||
M.C. Malin | Malin Space Science Systems | Improvement and validation of seasonal wind estimate methodology | |||||||||||||||||||||||||
M.C. Malin | Malin Space Science Systems | Acquisition, processing, early release, and mosaicing of Mars Orbiter Camera data |
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J.F. Mustard | Brown Univ. | Mineralogy maps of OMEGA data to support Mars exploration |
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D. Paige | Univ. of California, Los Angeles | Phoenix landing site ground ice depth map | |||||||||||||||||||||||||
T.J. Parker | Jet Propulsion Laboratory | Landing site map compilation for future Mars landers |
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M.D. Smith | Goddard Space Flight Center | Atmospheric characterization for Phoenix and MSL mission planning |
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M.T. Zuber | Goddard Space Flight Center | Planetary atmospheric variability of Mars from doppler tracking of Mars orbiters |
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R.E. Arvidson | Washington Univ. in St. Louis | Development, Testing, and Delivery of a Dynamic Mechanical Simulation for the 2003 Mars Exploration Rovers | Mars Exploration Rover mission – Crisp et al., 2003, J. Geophys. Res. 108 | ||||||||||||
S.W. Bougher | Univ. of Michigan | MGCM-MTGCM Simulated Data Files for an Improved Engineering Model of Mars Upper Atmospheric Densities for 2006-2009 |
Presentations
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P.R. Christensen | Arizona State Univ. | THEMIS Infrared and Visible Mosaic Pilot Project | THEMIS characterization of the MER Gusev crater landing site – Milam et al., 2003, J. Geophys. Res. 108 | ||||||||||||
B.M. Jakosky | Univ. of Colorado at Boulder | Thermal Inertia of the MER landing sites | |||||||||||||
G.M. Keating | George Washington Univ. | Archival of Mars Upper Atmosphere Properties Derived from Odyssey Accelerometer and Ancillary Data Collected During Aerobraking | Density variability at scales typical of gravity waves observed in Mars’ thermosphere by the MGS accelerometer – Creasley et al., 2006, Geophys. Res. Lett. 33 | ||||||||||||
T. Schofield | Jet Propulsion Laboratory | MER IMU data calibration and archival | |||||||||||||
L. Soderblom | U.S. Geological Survey, Flagstaff | Preparing for THEMIS Global Controlled Mosaics | |||||||||||||
G.M. Keating | George Washington Univ. | Archival of Mars Upper Atmosphere Properties Derived from Odyssey Accelerometer and Ancillary Data Collected During Aerobraking | Density variability at scales typical of gravity waves observed in Mars’ thermosphere by the MGS accelerometer – Creasley et al., 2006, Geophys. Res. Lett. 33 | ||||||||||||