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Space Topics: Phoenix

The Phoenix Landing Site

UPDATED MAY 19, 2008 WITH LATEST LANDING ELLIPSE LOCATION

When Phoenix lands on Mars on May 25, 2008, it will land at a site above Mars' "Arctic Circle," in a place where the annual freezing and vaporizing of water and carbon dioxide ice and frost have heaved and sculpted the ground into polygonally cracked patterns. The Sun will circle overhead 24.7 hours per day, supplying the lander with round-the-clock power as it digs beneath the surface for underground ice. The lander is aiming toward an area that the mission informally refers to as "Green Valley" (because it satisfies the landing site constraints so perfectly in all respects that it appears wholly green on the team's color-coded hazard maps). Green Valley is located within a group of hills called Scandia Colles, which lie within the broad, flat northern plains named Vastitas Borealis, at approximately 68.151 degrees north, 233.975 degrees east. Phoenix could land anywhere within an ellipse that is about 100 kilometers (62 miles) long and 19 kilometers (12 miles) wide. Phoenix targeted this location with a rocket firing on May 17, 2008.

Here are two views of the current landing ellipse location, one printed on a geologic map of the region, and one on a mosaic of Mars Reconnaissance Orbiter images of the region. Thanks to Tim Parker for providing the up-to-date map of the landing ellipse location. For more on what "landing ellipses" represent, read Rob Manning's explanations on The Planetary Society Weblog.

Click to enlarge > Phoenix landing site map as of May 19, 2008 Phoenix is scheduled to land May 25, 2008 in a region above Mars' Arctic Circle. Its 3-sigma landing ellipse (largest yellow oval, the region in which there is a 99% certainty that the lander will come to rest) is about 100 kilometers long and 19 kilometers wide, centered at 68.151 degrees north, 233.975 degrees east. This map is current as of May 19, 2008, a week before the landing, and accounts for a late northwestward shift of the target point. Credit: NASA / JPL-Caltech / Washington Univ. St. Louis / JHU APL / Univ. of Arizona / Tim Parker / Emily Lakdawalla

Click to enlarge > The Phoenix landing area The 1, 2, and 3-sigma landing ellipses for Phoenix are overlaid on a base map composed of images from Mars Reconnaissance Orbiter's HiRISE and CTX cameras. This map of the Phoenix landing site is up-to-date as of May 19, 2008. The center of the landing area is at 68.151N, 233.975E. Credit: NASA / JPL / U. Arizona / Tim Parker

Images from the Landing Site Area

The sharpest images of the landing site are from the HiRISE camera on Mars Reconnaissance Orbiter. Searching a box that ranges from 67.2 to 68.5 degrees north and 232 to 236.6 degrees east yields a list of images that cross the landing site region and reveal a wide variety of terrain that has been shaped by the seasonal motions of ground ice and water vapor. All the HiRISE images are oriented roughly north-south and are about 6.25 kilometers wide, so it would take about 16 individual, non-overlapping HiRISE swaths to cover the entire ellipse. Some representative images are:

PSP_001893_2485 crosses the western area of the ellipse (longitude 233.1)
PSP_006996_2480 crosses the center of the ellipse (longitude 233.8)
PSP_002104_2485 crosses the center of the ellipse (longitude 233.9)
PSP_002526_2485 crosses the center of the ellipse (longitude 234.1)
PSP_006640_2485 crosses the center of the ellipse (longitude 234.4)
PSP_006785_2485 crosses the east-central area of the ellipse (longitude 234.7)
PSP_006930_2480 catches the eastern edge of the ellipse (longitude 236.8)

What the area looks like at HiRISE resolution depends in large part on the time of year. When Mars Reconnaissance Orbiter began its work at Mars in November, 2006, it was late summer in the northern hemisphere, and the orbiter had very little time to work to capture images of the landing area before polar night descended. Images of the landing region showed hummocky patterned ground:

Sample terrain from Phoenix landing ellipse (late summer) A small sample of terrain from within the Phoenix landing ellipse as viewed by the HiRISE camera on Mars Reconnaissance Orbiter on January 7, 2007, when it was late summer in the northern hemisphere. The image is shown at a resolution of 50 centimeters per pixel and spans about 250 meters square. Credit: NASA / JPL / U. Arizona

During the winter, the region is covered to a depth of several tens of centimeters with a seasonal cap of carbon dioxide frost. When the Sun returned to the northern latitudes, it illuminated a landscape still dominated by frost, which fills the polygonal troughs in this image:

Sample terrain from Phoenix landing ellipse (early spring) A small sample of terrain from within the Phoenix landing ellipse as viewed by the HiRISE camera on Mars Reconnaissance Orbiter on January 3, 2008, when it was early spring in the northern hemisphere. Seasonal frost still fills the cracks between polygons. The image is shown at a resolution of 50 centimeters per pixel and spans about 250 meters square. Credit: NASA / JPL / U. Arizona

What are these polygons? Scientists agree that they form as a result of seasonal changes in temperature and humidity. However, the exact details are still poorly understood. On Earth, such polygonal terrain occurs as a result of actual melting of some of the water in the ground. The water runs through pre-existing cracks, and when it gets cold at night the water re-freezes. Because water expands when it cools, the new ice acts as a wedge, shoving the crack open. With each thaw and freeze cycle, the crack opens wider. On Mars, a drier process may be operating, in which dust acts as the wedging material. This is one question that Phoenix will seek to answer. The polygons seem to be slightly larger in scale than the Phoenix lander, but odds are good that Phoenix will land within arm's reach of a polygonal crack.

Once Phoenix lands, HiRISE should be able to spot the lander:

Simulated views of Phoenix lander This image simulates what the Phoenix lander might look like to the HiRISE camera aboard Mars Reconnaissance Orbiter after it lands on Mars in May 2008. A dozen simulated views of Phoenix are overlaid on an image of boulder-studded polygonal terrain of the northern plains. Phoenix will land so that its solar panels are oriented east-west and its robotic arm digs to the north. Credit: NASA / JPL / U. Arizona / Doug Ellison

Two other cameras on Mars Reconnaissance Orbiter provide views of the landing site at different resolutions. The Mars Color Imager (MARCI) is low-resolution but provides frequent global color views of Mars that permit monitoring of the weather; the Context Camera (CTX) takes medium-resolution views, intermediate between MARCI and HiRISE. The two images below were captured on April 20, 2008; the CTX image contains the first dust devils spotted at the Phoenix landing site this spring.

Click to enlarge > Dust devils at the Phoenix landing site The Context Camera on Mars Reconnaissance Orbiter repeatedly examined the near-polar landing site of Phoenix as spring came to the pole in early 2008. This image, taken on April 20, shows that nearly all of the seasonal polar ice cap has sublimated into the air (except for a few bright remnants within small craters), and also contains two towering dust devils. Measurement of the shadows indicated that one of the dust devils towered about 590 meters (~1,930 feet) with a dust plume extending 920 meters (~3,020 feet) above the surface. The other reached about 390 meters (~1,280 feet) high, with a dust plume extending to 790 meters (~2,590 feet). Credit: NASA / JPL / MSSS

Click to enlarge > The Phoenix landing ellipse The MARCI camera on Mars Reconnaissance Orbiter captured this image as part of its regular monitoring of Mars on April 20, 2008. The Phoenix landing ellipse is marked in white. An image was taken at the center of the ellipse simultaneously by the Context Camera, in which dust devils were visible. Credit: NASA / JPL / MSSS

Selecting the Site

The Phoenix team have had more data than any previous mission on which to base their choice of landing site. Their first priority is spacecraft safety, both for its landing and its operations. The landing site had to satisfy a number of constraints:

• be between 65 and 72 degrees north latitude;
• lie below an elevation of -3,500 meters;
• have winds blowing at less than 20 meters per second;
• have surface slopes shallower than 16 degrees; and
• have the same or fewer number of rocks scattered across the surface as at the Viking 2 Lander site (which had a rock areal abundance of 18%). 

In addition, to get the most science out of the mission, they must land in an area where Mars Odyssey's Gamma Ray Spectrometer sees evidence for abundant hydrogen (meaning abundant water) just below the surface. These and other initial criteria resulted in the mission focusing their efforts on an area of Mars between 67 and 70 degrees north latitude and 126 to 135 degrees east. However, once Mars Reconnaissance Orbiter arrived at Mars in November 2006 and began taking photos with its HiRISE camera, it became clear that the ground in this region was covered everywhere with boulders that were roughly the same size as Phoenix -- a potentially fatal hazard. So the mission had to quickly shift its focus to other potential sites. They settled upon a new region centered at 68.35 degrees North, 233 degrees East during a landing site selection meeting held in Pasadena, California in late January, 2007. A final tweak to the selected site occurred after launch, when the team elected to shift the landing ellipse downrange by about 13 kilometers in order to avoid some boulder-rich terrain at the northwest reach of the landing ellipse. The map at the top of this page accounts for that 13-kilometer shift.

(Last updated April 25, 2008)