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Modern Exploration Mars Odyssey. NASA’s theme for Mars exploration, “Follow the Water”, began with the 2001 Mars Odyssey mission Odyssey, and every mission since, has addressed the Mars programs’ four goals: Determine whether life ever arose on Mars Characterize the climate of Mars
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Modern ExplorationMars Odyssey • NASA’s theme for Mars exploration, “Follow the Water”, began with the 2001 Mars Odyssey mission • Odyssey, and every mission since, has addressed the Mars programs’ four goals: • Determine whether life ever arose on Mars • Characterize the climate of Mars • Characterize the geology of Mars • Prepare for human exploration
Modern ExplorationMars Odyssey • Objectives: • Determine the abundance of hydrogen, most likely in the form of water ice, in the shallow subsurface • Globally map the elements that make up the surface • Acquire high-resolution thermal infrared images of surface minerals • Provide information about the structure of the Martian surface • Record the radiation environment in low Mars orbit as it relates to radiation-related risk to human exploration
Modern ExplorationOdyssey • Launched April 7, 2001; arrived October 24, 2001 • 3 instruments: • Thermal Emission Imaging System (THEMIS); mineralogy • Gamma Ray Spectrometer (GRS); elemental composition • MartianRadiation Environment Experiment (MARIE)
Modern ExplorationOdyssey • Launched April 7, 2001; arrived October 24, 2001 • 3 instruments: • Thermal Emission Imaging System (THEMIS); mineralogy • Gamma Ray Spectrometer (GRS); elemental composition • MartianRadiation Environment Experiment (MARIE)
Modern ExplorationOdyssey Credit: NASA/JPL/University of Arizona
Modern ExplorationOdyssey Credit: NASA/JPL/University of Arizona
Modern ExplorationOdyssey • Notable results from Odyssey • Evidence for vast amounts of subsurface water ice at both polar regions • Can you see it?
Modern ExplorationOdyssey • Notable results from Odyssey • Evidence for vast amounts of subsurface water ice at both polar regions • Can you see it? • Where is it? • Underneath the surface but… • How deep? • Is it dirty ice? Or icy dirt?
Modern ExplorationOdyssey • How is Odyssey advancing scientific understanding of Mars? • Water-ice exists underneath the surface in the polar regions, not just at the poles • What technological advance(s) does Odyssey carry? • GRS; able to “look” below the surface
Modern ExplorationMars Reconnaissance Orbiter • “MRO is basically a spy satellite orbiting Mars.”
Modern ExplorationMRO • Objectives: • Characterize the present climate of Mars and how the climate changes from season-to-season and year-to-year • Characterize Mars’ global atmosphere and monitor its weather • Investigate complex terrain on Mars and identify water-related landforms • Search for sites showing stratigraphic or compositional evidence of water or hydrothermal activity
Modern ExplorationMRO • Objectives: • Probe beneath the surface for evidence of subsurface layering, water and ice, and profile the internal structure of the polar ice caps • Identify and characterize sites with the highest potential for future missions that will land on Mars’ surface, including possible missions to collect samples for returning to Earth • Relay scientific information to Earth from Mars surface missions.
Modern ExplorationMRO • Launched August 12, 2005; arrived March 10, 2006 • Aerobraked for 6 months, settling into its mapping orbit in November 2006
Modern ExplorationMRO • Instruments: • High Resolution Imaging Science Experiment (HiRISE); providing the highest-res images EVER (30 cm/pix) • Context Camera (CTX); wide-angle imagery • Mars Color Imager (MARCI) • Compact Reconnaissance Imaging Mars Climate Sounder (MCS); spectrometer • Shallow Radar (SHARAD)
Modern ExplorationMRO • Instruments: • High Resolution Imaging Science Experiment (HiRISE); providing the highest-res images EVER (30 cm/pix) • Context Camera (CTX); wide-angle imagery • Mars Color Imager (MARCI) • Compact Reconnaissance Imaging Mars Climate Sounder (MCS); spectrometer • Shallow Radar (SHARAD)
Modern ExplorationMRO • Instruments: • High Resolution Imaging Science Experiment (HiRISE); providing the highest-res images EVER (30 cm/pix) • Context Camera (CTX); wide-angle imagery • Mars Color Imager (MARCI) • Compact Reconnaissance Imaging Mars Climate Sounder (MCS); spectrometer • Shallow Radar (SHARAD)
Modern ExplorationMRO NASA/JPL-Caltech/University of Rome/SwRI
Modern ExplorationMRO All images courtesy of NASA/JPL-Caltech/University of Arizona
Modern ExplorationMRO All images courtesy of NASA/JPL-Caltech/University of Arizona
Modern ExplorationMRO Credit: NASA/JPL-Caltech/University of Arizona
Modern ExplorationMRO • Notable results from MRO • It’s difficult to list results considering MRO is ongoing • So much data coming back it will take years to go through the data, if it even all be analyzed (citizen science!!)
Modern ExplorationMRO • How is MRO advancing scientific understanding of Mars? • This is also difficult • Structure of ice cap • Better selection of landing sites • What technological advance(s) does MRO carry? • Highest-res camera EVER • Radar allowing us to peer under the ice cap(s)
Modern ExplorationMars Phoenix Lander • “The Phoenix has risen!” - Peter Smith, August 4, 2007
Modern ExplorationPhoenix • Objectives: • Study the history of water in the Martian arctic • Search for evidence of a habitable zone and assess the biological potential of the ice-soil boundary
Modern ExplorationPhoenix • Launched August 4, 2007; landed on May 25, 2008 on the northern arctic plains • Operated for ~6 months; unlike the MER rovers, Phoenix had no chance of surviving more than 6-7 months • First Mars mission run by a university – University of Arizona
Modern ExplorationPhoenix • Instruments: • Surface Stereo Imager (SSI); surface images • Thermal & Evolved Gas Analyzer (TEGA); organics detection • Microscopy, Electrochemistry, and Conductivity Analyzer (MECA); wet chemistry lab • Robotic Arm (RA); sampling & imaging • Robotic Arm Camera (RAC); imaging RA scoop before dumping samples, imaging below the lander deck • Meteorological Station (MET); daily weather, first LIDAR on Mars • Mars Descent Imager (MARDI); take images as Phoenix was landing
Modern ExplorationPhoenix All images courtesy of NASA/JPL-Caltech/University of Arizona/Texas A&M University
Modern ExplorationPhoenix Credit: NASA/JPL-Caltech/University of Arizona
Modern ExplorationPhoenix Credit: NASA/JPL-Caltech/University of Arizona
Modern Exploration Phoenix Credit: NASA/JPL-Caltech/University of Arizona
Modern ExplorationPhoenix Credit: NASA/JPL-Caltech/University of Arizona
Modern ExplorationPhoenix • Notable results from Phoenix • Confirmation of Odyssey/GRS measurements of subsurface water-ice • Detection of falling snow • Evidence from atmospheric studies that liquid water once flowed across the Martian surface • Perchlorate (toxic) found in the soils; caused the soil to be surprisingly sticky, very similar to soils in the Antarctic Dry Valleys
Modern ExplorationPhoenix • How did Phoenix advance scientific understanding of Mars? • Science is on-going • What technological advance(s) did Phoenix carry? • LIDAR (Light Detection and Ranging)
Future Exploration • What are the big questions that will guide future investigations of Mars? • Did life ever evolve on Mars? And, if so, does it still persist in the near- or deep-subsurface? • How does one reconcile the growing evidence that the ancient valley networks of Mars were formed by rainfall yet early Martian climate models fail to produce conditions suitable for water to exist as a liquid? • Did early Mars have a northern ocean? • Was the detection of methane in the Martian atmosphere real or the product of observational error? If real, what is the source of that methane?
A Final Thought • Success rate of all missions to Mars: 1/3 or 33% • Success rate of US missions to Mars: 2/3 or 66%