Mastcam-Z team blog: Landing sites


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DATE: Feb. 6, 2018, 11:26 a.m.

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  1. When you see an image from Mars do you ever contemplate what it took to bring it to you? You might imagine the feats of engineering that were required, but you may not have considered the lengthy process it took just to pick a place to land. For several years now, scientists from around the world have been gathering to discuss where we will send the next rover, Mars 2020. There have now been three formal landing site selection meetings, but even before those happen, individual scientists working on mission instrument teams have been devoting huge amounts of time to investigate the merits of the possible sites.
  2. Mastcam-Z team members at the February 2017 team meeting
  3. Elsa Jensen
  4. MASTCAM-Z TEAM MEMBERS AT THE FEBRUARY 2017 TEAM MEETING
  5. From left to right, in the order that their noses appear in the image: Jeff Johnson (APL), Sarah Fagents (Univ. Hawaii), Melissa Rice (WWU), Ken Herkenhoff (USGS/Flagstaff), Jake Adler (ASU), Sheridan Ackiss (Purdue), Noel Scudder (Purdue), Bob Deen (JPL, in front), Danika Wellington (ASU, behind), Mike Ravine (MSSS), Greg Mehall (ASU), Kristen Paris (ASU), Justin Maki (JPL, at very front), Rob Sullivan (Cornell), Ernest Cisneros (ASU), Adomas Valantinas (Univ. Copenhagen), Katherine Winchell (WWU), Alex Hayes (Cornell), Morten Bo Madsen (Univ. Copenhagen), Josh Williams (WWU), Darian Dixon (WWU), Briony Horgan (Purdue), Stephanie Shahrzad (Univ. Copenhagen), Kjartan Kinch (Univ. Copenhagen), Jim Bell (ASU), Zach Bailey (JPL).
  6. During our February 2017 team meeting, one of the important topics of conversation was the question of where our team thinks we should land the rover in 2021. The third official NASA Mars 2020 Landing Site Workshop would be held immediately afterward, so our primary focus was to review the eight remaining candidate landing sites and discuss whether we as a team thought some sites were more conducive to fulfilling the mission science objectives than others. We wanted to prepare our recommendations so that our favorite sites would not be voted off the island of Mars Landing Sites.
  7. Mars 2020 Mission Science Objectives:
  8. A. Geology. Characterize the processes that formed and modified the geologic record within a field exploration area on Mars selected for evidence of an astrobiologically-relevant ancient environment and geologic diversity.
  9. B. Astrobiology. Perform the following astrobiologically relevant investigations on the geologic materials at the landing site:
  10. Determine the habitability of an ancient environment.
  11. For ancient environments interpreted to have been habitable, search for materials with high biosignature preservation potential.
  12. Search for potential evidence of past life using the observations regarding habitability and preservation as a guide.
  13. C. Sample Caching. Assemble rigorously documented and returnable cached samples for possible future return to Earth.
  14. Obtain samples that are scientifically selected, for which the field context is documented, that contain the most promising samples identified in Objective B and that represent the geologic diversity of the field site.
  15. Ensure compliance with future needs in the areas of planetary protection and engineering so that the cached samples could be returned in the future if NASA chooses to do so.
  16. D. Preparation for Humans. Contribute to the preparation for human exploration of Mars by making significant progress towards filling at least one major Strategic Knowledge Gap (SKG). The highest priority SKG measurements that are synergistic with Mars 2020 science objectives and compatible with the mission concept are:
  17. Demonstration of In-Situ Resource Utilization (ISRU) technologies to enable propellant and consumable oxygen production from the Martian atmosphere for future exploration missions.
  18. Characterization of atmospheric dust size and morphology to understands its effects on the operation of surface systems and human health.
  19. Surface weather measurements to validate global atmospheric models.
  20. A set of engineering sensors embedded in the Mars 2020 heat shield and backshell to gather data on the aerothermal conditions, thermal protection system, and aerodynamic performance characteristics of the Mars 2020 entry vehicle during its entry and descent to the Mars surface.
  21. At both the team meeting and the landing site workshop that followed, we debated the pros and cons of all eight sites. At the end of the landing site workshop, the workshop leaders took a survey. The three sites that were selected for further study are Jezero, Columbia Hills, and Northeast Syrtis.
  22. The three potential landing sites for NASA's Mars 2020 rover
  23. NASA
  24. THE THREE POTENTIAL LANDING SITES FOR NASA'S MARS 2020 ROVER
  25. You can learn about the landing sites here. Following are some quick summaries.
  26. Jezero
  27. Site location: 18.4386N, 77.5031E, -2640m elevation, ellipse 10.7 x 8.3 km
  28. Detailed fact sheet about Jezero (PDF)
  29. Jezero is a 45-kilometer-wide impact crater that contains within it an ancient, eroded remnant of what may once have looked much like what we see of the Mississippi delta in Delta National Park. A major difference between these sites is that the Mississippi delta is only about 100 million years old, having formed during the Cretaceous period, whereas the Jezero delta is perhaps 3.5 to 3.8 billion years old. This is several billion years older than any delta that we see on Earth today! Earth has been so much more geologically active than Mars in the past few billion years that any evidence of ancient deltas on Earth has already been destroyed.
  30. Jezero Crater, Mars
  31. NASA / JPL-Caltech / MSSS / Tanya Harrison
  32. JEZERO CRATER, MARS
  33. This 10 m/pixel resolution mosaic of Jezero Crater was created from images taken by the Mars Reconnaissance Orbiter Context Camera (CTX). (Click on the image for a full-resolution view.)
  34. From orbital images, scientists have determined that Jezero once hosted a lake, about the size of Lake Tahoe or Lake Winnipeg, that had a watershed of over 30,000 square kilometers. It was an open basin, with two inflow channels and one outflow channel. To form a delta, water must flow through an area for a very long time, for thousands of years or more. The longer liquid water is present in an environment, the more hospitable it would have been for life. Deltas are also great for preserving evidence of life, if it developed on Mars. In Jezero crater, we see signs of clay minerals having been transported in to the lake, and we also see carbonate minerals that would have precipitated in the lake. On Earth, these kinds of minerals occurring in relatively low-energy sedimentary delta environments can preserve organic matter. So if life ever developed on Mars and occurred in Jezero crater or its watershed, the delta deposits could potentially preserve it.
  35. Outside of potential organic matter preservation, investigating Jezero geology could also help us put limits on how old the surface of Mars is. The crater floor appears to contain volcanic lava flows. One of the objectives of the Mars 2020 rover is to cache samples for their eventual return to Earth. If this mission succeeds and we are able to return samples, we could use radiometric dating to determine the absolute age of those lava flows. That, in turn, would allow us to pin one point in Mars' geologic history to a specific age and inform us about the maximum and minimum absolute ages of other terrains that pre- and postdate the lava flows on the crater floor.
  36. Columbia Hills
  37. Site location: 14.5478S, 175.6255E, -1930m elevation, ellipse 9.6 x 8.7 km
  38. Detailed fact sheet about Columbia Hills (PDF)
  39. The Mars Exploration Rover Spirit explored the Columbia Hills during its seven-year mission, from 2004 to 2010. Spirit's science team found a variety of geologic units along the traverse near the Columbia Hills within Gusev crater, including one volcanic unit and one potentially hydrothermal region. The landing site is volcanic, similar in composition to the Columbia River Flood Basalts in the U.S.'s Washington state. The main potential landing area of interest for Mars 2020 is a proposed hydrothermal site, which may have once been like some of the hydrothermal regions within Yellowstone National Park. The rover would have to land on the flat-lying volcanic rocks and trek about five kilometers to the interesting hydrothermal deposits. The drive could take from three to six months because Mars rovers move at only a fraction of average human walking speed, and available power usually limits their drives to one to two hours per day.
  40. Columbia Hills, Mars
  41. NASA / JPL-Caltech / MSSS / Tanya Harrison
  42. COLUMBIA HILLS, MARS
  43. This 5 m/pixel resolution mosaic of the Columbia Hills in Gusev Crater was created from images taken by the Mars Reconnaissance Orbiter Context Camera (CTX). (Click on the image for a full-resolution view.)
  44. During the initial several months of travel, the rover could sample and collect volcanic rocks. As described for Jezero, volcanic rock samples returned to Earth could help to put constraints on the age of this part of Mars. Once the rover arrives in the area of possible hydrothermal deposits, there is a wider variety of samples for it to collect, including volcaniclastics (rocks made up of older volcanic sediments), opaline silica (fine-grained silicon dioxide minerals, which may be hydrothermal and, on Earth, are sometimes formed biologically), and fine-grained sulfur-bearing minerals.
  45. Northeast Syrtis
  46. Site location: 17.8899N, 77.1599E, -2040m elevation, ellipse 11.1 x 18.2 km
  47. Detailed fact sheet about Northeast Syrtis (PDF)
  48. Northeast Syrtis Major is comparable in topography, although not in rock type, to Badlands National Park in South Dakota. It sits between two igneous volcanic regions and contains mixtures of volcanic and clay minerals. The presence of clays suggests significant past alteration by water. There are also carbonate and sulfate minerals, which not only indicate past water but can also be good at preserving "biosignatures", or evidence of preservation of organic matter. It has been proposed that many of these alteration minerals may have formed in a long-lived subsurface groundwater and spring system within this ancient volcanic terrain.
  49. Northeast Syrtis Major, Mars
  50. NASA / JPL-Caltech / MSSS / Tanya Harrison
  51. NORTHEAST SYRTIS MAJOR, MARS
  52. This 5 m/pixel resolution mosaic of the proposed landing region in NE Syrtis Major for NASA's Mars 2020 rover was created from images taken by the Mars Reconnaissance Orbiter Context Camera (CTX). (Click on the image for a full-resolution view.)
  53. This site is geologically very old. It is so old, in fact, that it could help us learn about the first four or five hundred million years of Mars’ four-and-a-half billion year history. The gases trapped inside the volcanic glasses at this site could tell us about the early history of the atmosphere of Mars (was it persistently warm and wet?), if we were to collect samples for analysis by the rover and eventually get them returned to Earth.
  54. Unlike the other two sites, Northeast Syrtis Major is a so-called "land-on" site. That is, the main regions of interest would probably be available to the rover immediately upon landing, without requiring months of driving.
  55. Next Steps in Landing Site Selection
  56. A date for the next landing site workshop hasn't been set yet. It will be exciting when we find out exactly where we are going to land so we can start to focus all of our energies in that direction! In the meantime, scientists and engineers around the world are working on the technical aspects of the 2020 rover, as well as further research on the remaining three sites to determine where would be best to land in 2021.

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