Search Results: All Fields similar to 'Viking' and When equal to '1999'

NASA Connect - GoE - Navigation To Mars and More Ellipses

NASA Connect - GoE - Navigat …

NASA Connect Segment that ex …

12/1/99

Description	NASA Connect Segment that explores how NASA scientists use geometry to navigate spacecraft from Earth to Mars. It also explains the goals and accomplishments of the Viking Mission.
Date	12/1/99

Movement of Whole Martian Dunes Difficult to Detect or Confirm

Movement of Whole Martian Du …

PIA02355

Sol (our sun)

Mars Orbiter Camera

Title	Movement of Whole Martian Dunes Difficult to Detect or Confirm
Original Caption Released with Image	Dunes on Earth move downwind at different speeds depending upon the local wind conditions, the amount of loose sand available to be transported by wind, the shape and volume of the dunes, and overgrowths of vegetation. Typically, smaller dunes move faster than larger dunes. On Earth, some of the fastest-moving dunes that have been measured (e.g., in the deserts of Peru) move 10 to 30 meters (33 to 100 feet) per year. Small dunes usually have an almost crescent-shape to them, and are known to geologists as barchan dunes. To look for evidence of dune movement on Mars, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) has been used to re-visit some areas of known barchan dunes--because these types move the fastest--that were observed by the Mariner 9 orbiter in 1972 and the Viking 1 and 2 orbiters between 1976 and 1980. The picture above, left, shows a MOC high-resolution image taken December 25, 1999. The classic, crescentic shape of the dark barchan dunes can be seen in this picture. The steep slopes, also known as the dune slip faces, on these dunes are facing toward the southwest (north is up in both pictures). Thus, the shape of the dunes indicates that they are moving toward the southwest. The picture above right shows the MOC image from December 1999 superimposed on a Viking 1 image taken May 27, 1978. During the 11 1/2 Mars years that passed between these two dates, it turns out that no difference can be detected in the position of the dunes seen in the MOC image and the Viking image. The earlier Viking image had a resolution of about 17 meters (56 ft) per pixel, while the MOC image had a resolution of about 3.8 meters (12 ft) per pixel. Although it looks like the dunes didn't move between the Viking and MOC images, this observation is limited by the resolution of the Viking image. It is entirely possible that the dunes have moved as much as 17-20 meters (16-66 ft) and one would not be able to tell by comparing the images. As it is, movement of less than 20 meters (66 ft) in 11 martian years (nearly 22 Earth years) is slower than some dunes of similar size and shape on Earth. Thus, it appears that martian dunes are not "experiencing" the level of activity commonly reported for some of the modern desert dunes found on Earth. The dune field illustrated in these pictures is located in a western Arabia Terra crater at 1.6°N, 351.6°W. Both the Viking and MOC images are illuminated from the left.

Movement of Whole Martian Du …

PIA02355

Sol (our sun)

Mars Orbiter Camera

Title	Movement of Whole Martian Dunes Difficult to Detect or Confirm
Original Caption Released with Image	Dunes on Earth move downwind at different speeds depending upon the local wind conditions, the amount of loose sand available to be transported by wind, the shape and volume of the dunes, and overgrowths of vegetation. Typically, smaller dunes move faster than larger dunes. On Earth, some of the fastest-moving dunes that have been measured (e.g., in the deserts of Peru) move 10 to 30 meters (33 to 100 feet) per year. Small dunes usually have an almost crescent-shape to them, and are known to geologists as barchan dunes. To look for evidence of dune movement on Mars, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) has been used to re-visit some areas of known barchan dunes--because these types move the fastest--that were observed by the Mariner 9 orbiter in 1972 and the Viking 1 and 2 orbiters between 1976 and 1980. The picture above, left, shows a MOC high-resolution image taken December 25, 1999. The classic, crescentic shape of the dark barchan dunes can be seen in this picture. The steep slopes, also known as the dune slip faces, on these dunes are facing toward the southwest (north is up in both pictures). Thus, the shape of the dunes indicates that they are moving toward the southwest. The picture above right shows the MOC image from December 1999 superimposed on a Viking 1 image taken May 27, 1978. During the 11 1/2 Mars years that passed between these two dates, it turns out that no difference can be detected in the position of the dunes seen in the MOC image and the Viking image. The earlier Viking image had a resolution of about 17 meters (56 ft) per pixel, while the MOC image had a resolution of about 3.8 meters (12 ft) per pixel. Although it looks like the dunes didn't move between the Viking and MOC images, this observation is limited by the resolution of the Viking image. It is entirely possible that the dunes have moved as much as 17-20 meters (16-66 ft) and one would not be able to tell by comparing the images. As it is, movement of less than 20 meters (66 ft) in 11 martian years (nearly 22 Earth years) is slower than some dunes of similar size and shape on Earth. Thus, it appears that martian dunes are not "experiencing" the level of activity commonly reported for some of the modern desert dunes found on Earth. The dune field illustrated in these pictures is located in a western Arabia Terra crater at 1.6°N, 351.6°W. Both the Viking and MOC images are illuminated from the left.

Evidence for Recent Liquid Water on Mars

Evidence for Recent Liquid W …

Title	Evidence for Recent Liquid Water on Mars
Full Description	Gullies eroded into the wall of a meteor impact crater in Noachis Terra. This high resolution view (top left) from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) shows channels and associated aprons of debris that are interpreted to have formed by groundwater seepage, surface runoff, and debris flow. The lack of small craters superimposed on the channels and apron deposits indicates that these features are geologically young. It is possible that these gullies indicate that liquid water is present within the martian subsurface today. The MOC image was acquired on September 28, 1999. The scene covers an area approximately 3 kilometers (1.9 miles) wide by 6.7 km (4.1 mi) high (note, the aspect ratio is 1.5 to 1.0). Sunlight illuminates this area from the upper left. The image is located near 54.8S, 342.5W. The context image (above) shows the location of the MOC image on the south-facing wall of an impact crater approximately 20 kilometers (12 miles) in diameter. The context picture was obtained by the Viking 1 orbiter in 1980 and is illuminated from the upper left. The large mound on the floor of the crater in the context view is a sand dune field. The Mars Orbiter Camera high resolution images are taken black-and-white (grayscale), the color seen here has been synthesized from the colors of Mars observed by the MOC wide angle cameras and by the Viking Orbiters in the late 1970s. A brief description of how the color was generated: The MOC narrow angle camera only takes grayscale (black and white) pictures. To create the color versions seen here, we have taken much lower resolution red and blue images acquired by the MOC's wide angle cameras, and by the Viking Orbiter cameras in the 1970s, synthesized a green image by averaging red and blue, and created a pallete of colors that represent the range of colors on Mars. We then use a relationship that correlates color and brightness to assign a color to each gray level. This is only a crude approximation of martian color. It is likely Mars would not look like this to a human observer at Mars.
Date	06/22/2000
NASA Center	Jet Propulsion Laboratory

Mutch Crater

PIA08709

Sol (our sun)

Title	Mutch Crater
Original Caption Released with Image	27 August 2006 Thomas A. Mutch has been called an explorer of two worlds. Known to colleagues as Tim, he was born on August 26, 1931. An avid mountaineer as well as a scientist, he climbed in the Canadian Rockies and the Himalayas, and had a passion for exploration in all its forms. Mutch became a geologist after majoring in history at Princeton, he received a master's degree from Rutgers and a doctorate from Princeton. In 1960 he became a geology professor at Brown University, later serving as department chairman. In the late 1960s, Mutch applied the geologic discipline called stratigraphy to the study of features on the Moon, work that led to his writing the landmark book, "The Geology of the Moon". Mutch went on to become the leader of the Viking Lander Imaging Team, which had responsibility for obtaining and interpreting the first images from the surface of Mars. Following the successful touchdowns of Viking 1 on July 20, 1976 and Viking 2 a few weeks later, the twin landers transmitted a total of more than 4,000 images from the Martian surface. Mutch had an ability to inspire those around him and a dedication to involving young people in the experience of exploration. He helped create the Viking Student Intern program, a pioneering educational activity since duplicated by many planetary missions, which allowed several dozen college students to participate in the Viking mission. At Brown, where he taught a seminar in exploration, he invited students to participate in a Himalayan climbing expedition. In May 1978, Mutch led a team of 32 students, faculty, and alumni to the21,900-foot Indian peak Devistan, 24 of them, including Mutch, made it to the summit. In October 1980, Mutch died on the slopes of Mount Nun in the Himalayas, following a climbing accident while descending from the 23,410-foot summit. At the time he was on leave from Brown, serving as NASA's Associate Administrator for Space Science. His legacy endures in the many minds and spirits he helped nurture. In the planetary science community his former students include R. Stephen Saunders, James W. Head, III, Raymond E. Arvidson, and James B. Garvin. In 1981, NASA administrator Robert Frosch announced that the Viking 1 lander had been renamed the Mutch Memorial Station, and unveiled a stainless steel plaque that is to be placed on the lander, someday, by a team of explorers. The inscription on the plaque reads, "Dedicated to the memory of Tim Mutch, whose imagination, verve, and resolve contributed greatly to the exploration of the Solar System." Located at 0.6°N, 55.3°W, Mutch Crater is about 211 kilometers (131 miles) in diameter. Naming of this crater for Tim Mutch was approved by the International Astronomical Union (IAU) in 1985. The main image is a mosaic of Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) red wide angle images acquired during the MOC Geodesy Campaign [ http://www.msss.com/mars_images/moc/5_17_99_geodesy/ ], in May 1999. The white boxes show the location of figures 1 and 2. Figure 1 is a mosaic of MOC and lower-resolution Mars Odyssey THEMIS VIS images that cover a smaller, unnamed crater located in west-central Mutch Crater. Figure 2 is a portion of the mosaic of the small, unnamed crater, showing landslide deposits formed when material slumped off the crater wall. The source alcoves of the landslides are well defined, as are longitudinal troughs and ridges on the surface of the landslides. These mass movements occurred long after the crater was formed, judging by the difference in the number of small impact craters on their surfaces and on the nearby floor of the crater. The view of the landslides in the northeast corner of the small, unnamed crater in Mutch was acquired by the MGS MOC just a few days ago, on 23 August 2006, to commemorate the 75th birthday of Tim Mutch on 26 August 2006. Noted space writer Andrew Chaikin (http://www.andrewchaikin.com [ http://www.andrewchaikin.com ]), a former Tim Mutch student, suggested the 23 August 2006 MGS MOC image and contributed to the text of this release.

Mutch Crater

PIA08709

Sol (our sun)

Title	Mutch Crater
Original Caption Released with Image	27 August 2006 Thomas A. Mutch has been called an explorer of two worlds. Known to colleagues as Tim, he was born on August 26, 1931. An avid mountaineer as well as a scientist, he climbed in the Canadian Rockies and the Himalayas, and had a passion for exploration in all its forms. Mutch became a geologist after majoring in history at Princeton, he received a master's degree from Rutgers and a doctorate from Princeton. In 1960 he became a geology professor at Brown University, later serving as department chairman. In the late 1960s, Mutch applied the geologic discipline called stratigraphy to the study of features on the Moon, work that led to his writing the landmark book, "The Geology of the Moon". Mutch went on to become the leader of the Viking Lander Imaging Team, which had responsibility for obtaining and interpreting the first images from the surface of Mars. Following the successful touchdowns of Viking 1 on July 20, 1976 and Viking 2 a few weeks later, the twin landers transmitted a total of more than 4,000 images from the Martian surface. Mutch had an ability to inspire those around him and a dedication to involving young people in the experience of exploration. He helped create the Viking Student Intern program, a pioneering educational activity since duplicated by many planetary missions, which allowed several dozen college students to participate in the Viking mission. At Brown, where he taught a seminar in exploration, he invited students to participate in a Himalayan climbing expedition. In May 1978, Mutch led a team of 32 students, faculty, and alumni to the21,900-foot Indian peak Devistan, 24 of them, including Mutch, made it to the summit. In October 1980, Mutch died on the slopes of Mount Nun in the Himalayas, following a climbing accident while descending from the 23,410-foot summit. At the time he was on leave from Brown, serving as NASA's Associate Administrator for Space Science. His legacy endures in the many minds and spirits he helped nurture. In the planetary science community his former students include R. Stephen Saunders, James W. Head, III, Raymond E. Arvidson, and James B. Garvin. In 1981, NASA administrator Robert Frosch announced that the Viking 1 lander had been renamed the Mutch Memorial Station, and unveiled a stainless steel plaque that is to be placed on the lander, someday, by a team of explorers. The inscription on the plaque reads, "Dedicated to the memory of Tim Mutch, whose imagination, verve, and resolve contributed greatly to the exploration of the Solar System." Located at 0.6°N, 55.3°W, Mutch Crater is about 211 kilometers (131 miles) in diameter. Naming of this crater for Tim Mutch was approved by the International Astronomical Union (IAU) in 1985. The main image is a mosaic of Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) red wide angle images acquired during the MOC Geodesy Campaign [ http://www.msss.com/mars_images/moc/5_17_99_geodesy/ ], in May 1999. The white boxes show the location of figures 1 and 2. Figure 1 is a mosaic of MOC and lower-resolution Mars Odyssey THEMIS VIS images that cover a smaller, unnamed crater located in west-central Mutch Crater. Figure 2 is a portion of the mosaic of the small, unnamed crater, showing landslide deposits formed when material slumped off the crater wall. The source alcoves of the landslides are well defined, as are longitudinal troughs and ridges on the surface of the landslides. These mass movements occurred long after the crater was formed, judging by the difference in the number of small impact craters on their surfaces and on the nearby floor of the crater. The view of the landslides in the northeast corner of the small, unnamed crater in Mutch was acquired by the MGS MOC just a few days ago, on 23 August 2006, to commemorate the 75th birthday of Tim Mutch on 26 August 2006. Noted space writer Andrew Chaikin (http://www.andrewchaikin.com [ http://www.andrewchaikin.com ]), a former Tim Mutch student, suggested the 23 August 2006 MGS MOC image and contributed to the text of this release.

Mutch Crater

PIA08709

Sol (our sun)

Title	Mutch Crater
Original Caption Released with Image	27 August 2006 Thomas A. Mutch has been called an explorer of two worlds. Known to colleagues as Tim, he was born on August 26, 1931. An avid mountaineer as well as a scientist, he climbed in the Canadian Rockies and the Himalayas, and had a passion for exploration in all its forms. Mutch became a geologist after majoring in history at Princeton, he received a master's degree from Rutgers and a doctorate from Princeton. In 1960 he became a geology professor at Brown University, later serving as department chairman. In the late 1960s, Mutch applied the geologic discipline called stratigraphy to the study of features on the Moon, work that led to his writing the landmark book, "The Geology of the Moon". Mutch went on to become the leader of the Viking Lander Imaging Team, which had responsibility for obtaining and interpreting the first images from the surface of Mars. Following the successful touchdowns of Viking 1 on July 20, 1976 and Viking 2 a few weeks later, the twin landers transmitted a total of more than 4,000 images from the Martian surface. Mutch had an ability to inspire those around him and a dedication to involving young people in the experience of exploration. He helped create the Viking Student Intern program, a pioneering educational activity since duplicated by many planetary missions, which allowed several dozen college students to participate in the Viking mission. At Brown, where he taught a seminar in exploration, he invited students to participate in a Himalayan climbing expedition. In May 1978, Mutch led a team of 32 students, faculty, and alumni to the21,900-foot Indian peak Devistan, 24 of them, including Mutch, made it to the summit. In October 1980, Mutch died on the slopes of Mount Nun in the Himalayas, following a climbing accident while descending from the 23,410-foot summit. At the time he was on leave from Brown, serving as NASA's Associate Administrator for Space Science. His legacy endures in the many minds and spirits he helped nurture. In the planetary science community his former students include R. Stephen Saunders, James W. Head, III, Raymond E. Arvidson, and James B. Garvin. In 1981, NASA administrator Robert Frosch announced that the Viking 1 lander had been renamed the Mutch Memorial Station, and unveiled a stainless steel plaque that is to be placed on the lander, someday, by a team of explorers. The inscription on the plaque reads, "Dedicated to the memory of Tim Mutch, whose imagination, verve, and resolve contributed greatly to the exploration of the Solar System." Located at 0.6°N, 55.3°W, Mutch Crater is about 211 kilometers (131 miles) in diameter. Naming of this crater for Tim Mutch was approved by the International Astronomical Union (IAU) in 1985. The main image is a mosaic of Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) red wide angle images acquired during the MOC Geodesy Campaign [ http://www.msss.com/mars_images/moc/5_17_99_geodesy/ ], in May 1999. The white boxes show the location of figures 1 and 2. Figure 1 is a mosaic of MOC and lower-resolution Mars Odyssey THEMIS VIS images that cover a smaller, unnamed crater located in west-central Mutch Crater. Figure 2 is a portion of the mosaic of the small, unnamed crater, showing landslide deposits formed when material slumped off the crater wall. The source alcoves of the landslides are well defined, as are longitudinal troughs and ridges on the surface of the landslides. These mass movements occurred long after the crater was formed, judging by the difference in the number of small impact craters on their surfaces and on the nearby floor of the crater. The view of the landslides in the northeast corner of the small, unnamed crater in Mutch was acquired by the MGS MOC just a few days ago, on 23 August 2006, to commemorate the 75th birthday of Tim Mutch on 26 August 2006. Noted space writer Andrew Chaikin (http://www.andrewchaikin.com [ http://www.andrewchaikin.com ]), a former Tim Mutch student, suggested the 23 August 2006 MGS MOC image and contributed to the text of this release.

Solar System Montage

Title	Solar System Montage
Full Description	This is a montage of planetary images taken by spacecraft managed by the Jet Propulsion Laboratory in Pasadena, CA. Included are (from top to bottom) images of Mercury, Venus, Earth (and Moon), Mars, Jupiter, Saturn, Uranus and Neptune. The spacecraft responsible for these images are as follows: the Mercury image was taken by Mariner 10, the Venus image by Magellan, the Earth image by Galileo, the Mars image by Viking, and the Jupiter, Saturn, Uranus and Neptune images by Voyager. Pluto is not shown as no spacecraft has yet visited it. The inner planets (Mercury, Venus, Earth, Moon, and Mars) are roughly to scale to each other, the outer planets (Jupiter, Saturn, Uranus, and Neptune) are roughly to scale to each other. Actual diameters are given below: Sun 1,390,000 km Mercury 4,879 km Venus 12,104 km Earth 12,756 km Moon 3,475 km Mars 6,794 km Jupiter 142.984 km Saturn 120,536 km Uranus 51,118 km Neptune 49,528 km Pluto 2,390 km
Date	04/09/1999
NASA Center	Jet Propulsion Laboratory

Detailed View of Cliff-face in the North Polar Layered Deposits

Detailed View of Cliff-face …

PIA01479

Sol (our sun)

Mars Orbiter Camera

Title	Detailed View of Cliff-face in the North Polar Layered Deposits
Original Caption Released with Image	On Earth, geologists use layers of rock to "read" the history of our planet. Where rocks were initially formed as layers of sediment, the historic record of Earth is deciphered by knowing that older layers are found beneath the younger layers. Scientists investigating changes in Earth's climate over the past few million years also use this principle to examine cores of ice from Greenland and Antarctica. Layered rock and layered polar deposits on Mars may also preserve a comparable record of that planet's geologic and environmental history. The martian north and south polar regions are covered by large areas of layered deposits. Since their discovery in the early 1970's, these polar layered deposits have been cited as the best evidence that the martian climate experiences cyclic changes over time. It was proposed that detailed investigation of the polar layers ("e.g.,", by landers and/or human beings) would reveal a climate record of Mars in much the same way that ice cores from Antarctica are used to study past climates on Earth. On January 3, 1999, NASA's Mars Polar Lander and Deep Space 2 Penetrators will launch on a journey to study the upper layers of these deposits in the martian southern hemisphere. Meanwhile, investigation of the north polar layered deposits has advanced significantly this year with the acquisition of MGS data. The Mars Orbiter Laser Altimeter acquired new topographic profiles over the north polar deposits in June and early July, 1998, and dozens of new high resolution images were taken by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) from mid-July to mid-September, 1998. When it was proposed to NASA in 1985, one of the original objectives of MOC was to determine whether the polar layered deposits--then thought to consist of 10 to 100 layers each between 10 and 100 meters (33 to 330 feet) thick--have more and thinner layers in them. The layers were proposed to have formed by slow accumulation of dust and ice--perhaps only 100 micrometers (0.004 inches) per year. A layer 10 meters (33 feet) thick would take 100,000 years to accumulate, roughly equal to the timescale of climate changes predicted by computer models. The image shown here (right image) was taken at 11:52 p.m. PDT on July 30, 1998, near the start of the 461st orbit of Mars Global Surveyor. The picture shows a slope along the edge of the permanent north polar cap of Mars that has dozens of layers exposed in it. The image shows many more layers than were visible to the Viking Orbiters in the 1970s (left images). The layers appear to have different thicknesses (some thinner than 10 meters (33 feet)) and different physical expressions. Some of the layers form steeper slopes than others, suggesting that they are more resistant to erosion. The more resistant layers might indicate that a cement (possibly ice) is present, making those layers stronger. All of the layers appear to have a rough texture that might be the result of erosion and/or redistribution of sediment and polar ice on the slope surface. The presence of many more layers than were seen by Viking is an important and encouraging clue that suggests that future investigation of polar layered deposits by landers and, perhaps some day, by human explorers, will eventually lead to a better understanding of the of the polar regions and the climate history recorded there. Our view of these deposits will be much improved--starting in late March 1999--when the Mapping Phase of the MGS mission begins, and MOC will be able to obtain images with resolutions of 1.5 meters (5 feet) per pixel. [The Viking Images (left)]: Regional and local context of MOC image 46103. The small figure in the upper right corner is a map of the north polar region, centered on the pole with 0° longitude located in the lower middle of the frame. A small black box within the polar map indicates, the location of the Viking Orbiter 2 image used here for local context. The Viking image, 560b60, was taken in March 1978, toward the end of Northern Spring. The thin strip superposed on the Viking image is MOC image 46103, reduced in size to mark its placement relative to the Viking context image. The black box on the MOC image shows the location of the subframe highlighted here (right image). Illumination is from the left in the Viking image. The 10 kilometer scale bar also represents approximately 6.2 miles. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

Mars and Syrtis Major

Title	Mars and Syrtis Major
Full Description	Taking advantage of Mars's closest approach to Earth in eight years, astronomers using NASA's Hubble Space Telescope have taken the space- based observatory's sharpest views yet of the Red Planet. The telescope's Wide Field and Planetary Camera 2 snapped these images between April 27 and May 6, when Mars was 54 million miles (87 million kilometers) from Earth. From this distance the telescope could see Martian features as small as 12 miles (19 kilometers) wide. The telescope obtained four images, which, together, show the entire planet. Each view depicts the planet as it completes one quarter of its daily rotation. In these views the north polar cap is tilted toward the Earth and is visible prominently at the top of each picture. The images were taken in the middle of the Martian northern summer, when the polar cap had shrunk to its smallest size. During this season the Sun shines continuously on the polar cap. Previous telescopic and spacecraft observations have shown that this summertime "residual" polar cap is composed of water ice, just like Earth's polar caps. These Hubble telescope snapshots reveal that substantial changes in the bright and dark markings on Mars have occurred in the 20 years since the NASA Viking spacecraft missions first mapped the planet. The Martian surface is dynamic and ever changing. Some regions that were dark 20 years ago are now bright red, some areas that were bright red are now dark. Winds move sand and dust from region to region, often in spectacular dust storms. Over long timescales many of the larger bright and dark markings remain stable, but smaller details come and go as they are covered and then uncovered by sand and dust. The dark feature known as Syrtis Major was first seen telescopically by the astronomer Christiaan Huygens in the 17th century. Many small, dark, circular impact craters can be seen in this region, attesting to the Hubble telescope's ability to reveal fine detail on the planet's surface. To the south of Syrtis is a large circular feature called Hellas. Viking and more recently Mars Global Surveyor have revealed that Hellas is a large and deep impact crater. These Hubble telescope pictures show it to be filled with surface frost and water ice clouds. Along the right limb, late afternoon clouds have formed around the volcano Elysium.
Date	06/30/1999
NASA Center	Hubble Space Telescope Center

MOC Providing Clues For Future Landing Site Selection

MOC Providing Clues For Futu …

PIA02064

Sol (our sun)

Mars Orbiter Camera

Title	MOC Providing Clues For Future Landing Site Selection
Original Caption Released with Image	One of the original objectives of the Mars Orbiter Camera (MOC) when it was proposed to NASA in 1985 was to take pictures that would be used to assess future spacecraft landing sites. Images obtained by the Mars Global Surveyor (MGS) MOC since March 1999 provide the highest resolution views (1.5 to 4.5 meters (5-15 ft) per pixel) of the planet ever seen. Over the past several months, MOC science personnel have been examining these new data to develop a general view of what Mars is like at the meter-scale within the general latitude and elevation range that will be accessible to the Mars Surveyor 2001 lander [ http://marsweb.jpl.nasa.gov/2001/index.html ]. (i.e., about 5°N to 15°S latitude and lower than 2.5 km (1.6 mi) elevation). Because MOC images only cover a tiny fraction of one percent of the surface of Mars, we have been seeking general correlations that exist between what is seen in a MOC high-resolution image and what can be seen in the lower-resolution Viking and Mariner 9 images taken in 1972 and 1976-1980. The most important results thus far are illustrated in the four pictures above. Nearly 70% of the terrain examined follows two very simple, but unexpected "rules" -- (1) If the terrain appears rugged at the hundreds of meters to kilometers scale in a Viking or Mariner image, then it will appear smooth at the meter-scale in a MOC image. (2) If the terrain appears to be smooth in the Viking or Mariner image, it will be rough in the meter-scale MOC image. The image pair above illustrates the second "rule." Areas that appear to be smooth in the Viking and Mariner images--as in MOC2-138a (left)--tend to look quite rough at the meter scale in MOC images like MOC2-138b (right). The rough texture in this particular case was probably cause by wind erosion. The Viking image shown here is illuminated from the upper right, while the MOC image is illuminated from the upper left. The MOC image was taken in April 1999, while the Viking image was obtained in the late 1970s. More details about this work are provided in an extended abstract (in Acrobat® PDF format) by M.C. Malin, K. S. Edgett, and T. J. Parker, "Characterization of terrain in the Mars Surveyor 2001 landing site latitude and elevation region using Mapping Phase Mars Global Surveyor MOC images," [ http://www.msss.com/mars/global_surveyor/camera/images/6_25_99_landingsites/malin_buffalo_abs.pdf ] presented at the Second Mars Surveyor Landing Site Workshop, held June 22-23, 1999, in Buffalo, New York. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

MOC Providing Clues For Futu …

PIA02064

Sol (our sun)

Mars Orbiter Camera

Title	MOC Providing Clues For Future Landing Site Selection
Original Caption Released with Image	One of the original objectives of the Mars Orbiter Camera (MOC) when it was proposed to NASA in 1985 was to take pictures that would be used to assess future spacecraft landing sites. Images obtained by the Mars Global Surveyor (MGS) MOC since March 1999 provide the highest resolution views (1.5 to 4.5 meters (5-15 ft) per pixel) of the planet ever seen. Over the past several months, MOC science personnel have been examining these new data to develop a general view of what Mars is like at the meter-scale within the general latitude and elevation range that will be accessible to the Mars Surveyor 2001 lander [ http://marsweb.jpl.nasa.gov/2001/index.html ]. (i.e., about 5°N to 15°S latitude and lower than 2.5 km (1.6 mi) elevation). Because MOC images only cover a tiny fraction of one percent of the surface of Mars, we have been seeking general correlations that exist between what is seen in a MOC high-resolution image and what can be seen in the lower-resolution Viking and Mariner 9 images taken in 1972 and 1976-1980. The most important results thus far are illustrated in the four pictures above. Nearly 70% of the terrain examined follows two very simple, but unexpected "rules" -- (1) If the terrain appears rugged at the hundreds of meters to kilometers scale in a Viking or Mariner image, then it will appear smooth at the meter-scale in a MOC image. (2) If the terrain appears to be smooth in the Viking or Mariner image, it will be rough in the meter-scale MOC image. The image pair above illustrates the second "rule." Areas that appear to be smooth in the Viking and Mariner images--as in MOC2-138a (left)--tend to look quite rough at the meter scale in MOC images like MOC2-138b (right). The rough texture in this particular case was probably cause by wind erosion. The Viking image shown here is illuminated from the upper right, while the MOC image is illuminated from the upper left. The MOC image was taken in April 1999, while the Viking image was obtained in the late 1970s. More details about this work are provided in an extended abstract (in Acrobat® PDF format) by M.C. Malin, K. S. Edgett, and T. J. Parker, "Characterization of terrain in the Mars Surveyor 2001 landing site latitude and elevation region using Mapping Phase Mars Global Surveyor MOC images," [ http://www.msss.com/mars/global_surveyor/camera/images/6_25_99_landingsites/malin_buffalo_abs.pdf ] presented at the Second Mars Surveyor Landing Site Workshop, held June 22-23, 1999, in Buffalo, New York. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

'Happy Face' Crater

title	'Happy Face' Crater
date	03.10.1999
description	Mars Global Surveyor was greeted with this view of 'Happy Face Crater' smiling back at its camera from its location on the east side of Argyre Planitia. This crater is officially known as Galle Crater, and it is about 215 kilometers (134 miles) across. The picture was taken by the MOC's red and blue wide angle cameras. The bluish-white tone is caused by wintertime frost. Illumination is from the upper left. For more information and Viking Orbiter views of "Happy Face Crater," see http://www.msss.com/education/happy_face/happy_face.html. Image Credit: NASA

MOC Providing Clues For Futu …

PIA02063

Sol (our sun)

Mars Orbiter Camera

Title	MOC Providing Clues For Future Landing Site Selection
Original Caption Released with Image	One of the original objectives of the Mars Orbiter Camera (MOC) when it was proposed to NASA in 1985 was to take pictures that would be used to assess future spacecraft landing sites. Images obtained by the Mars Global Surveyor (MGS) MOC since March 1999 provide the highest resolution views (1.5 to 4.5 meters (5-15 ft) per pixel) of the planet ever seen. Over the past several months, MOC science personnel have been examining these new data to develop a general view of what Mars is like at the meter-scale within the general latitude and elevation range that will be accessible to the Mars Surveyor 2001 lander [ http://marsweb.jpl.nasa.gov/2001/index.html ]. (i.e., about 5°N to 15°S latitude and lower than 2.5 km (1.6 mi) elevation). Because MOC images only cover a tiny fraction of one percent of the surface of Mars, we have been seeking general correlations that exist between what is seen in a MOC high-resolution image and what can be seen in the lower-resolution Viking and Mariner 9 images taken in 1972 and 1976-1980. The most important results thus far are illustrated in the four pictures above. Nearly 70% of the terrain examined follows two very simple, but unexpected "rules" -- (1) If the terrain appears rugged at the hundreds of meters to kilometers scale in a Viking or Mariner image, then it will appear smooth at the meter-scale in a MOC image. (2) If the terrain appears to be smooth in the Viking or Mariner image, it will be rough in the meter-scale MOC image. The image pair above illustrates the first "rule." MOC2-137a (left) shows a rugged plain in the martian southern cratered highlands near the Nepenthes Mensae. The small white box indicates the location of the MOC image, which is on the right (MOC2-137b). The MOC image reveals that while the terrain is rough at the large scale, it is quite smooth at the meter-scale. The Viking image shown here is illuminated from the upper right, while the MOC image is illuminated from the upper left. The MOC image was taken in April 1999, while the Viking image was obtained in the late 1970s. More details about this work are provided in an extended abstract (in Acrobat® PDF format) by M.C. Malin, K. S. Edgett, and T. J. Parker, "Characterization of terrain in the Mars Surveyor 2001 landing site latitude and elevation region using Mapping Phase Mars Global Surveyor MOC images," [ http://www.msss.com/mars/global_surveyor/camera/images/6_25_99_landingsites/malin_buffalo_abs.pdf ], presented at the Second Mars Surveyor Landing Site Workshop, held June 22-23, 1999, in Buffalo, New York. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

MOC Providing Clues For Futu …

PIA02063

Sol (our sun)

Mars Orbiter Camera

Title	MOC Providing Clues For Future Landing Site Selection
Original Caption Released with Image	One of the original objectives of the Mars Orbiter Camera (MOC) when it was proposed to NASA in 1985 was to take pictures that would be used to assess future spacecraft landing sites. Images obtained by the Mars Global Surveyor (MGS) MOC since March 1999 provide the highest resolution views (1.5 to 4.5 meters (5-15 ft) per pixel) of the planet ever seen. Over the past several months, MOC science personnel have been examining these new data to develop a general view of what Mars is like at the meter-scale within the general latitude and elevation range that will be accessible to the Mars Surveyor 2001 lander [ http://marsweb.jpl.nasa.gov/2001/index.html ]. (i.e., about 5°N to 15°S latitude and lower than 2.5 km (1.6 mi) elevation). Because MOC images only cover a tiny fraction of one percent of the surface of Mars, we have been seeking general correlations that exist between what is seen in a MOC high-resolution image and what can be seen in the lower-resolution Viking and Mariner 9 images taken in 1972 and 1976-1980. The most important results thus far are illustrated in the four pictures above. Nearly 70% of the terrain examined follows two very simple, but unexpected "rules" -- (1) If the terrain appears rugged at the hundreds of meters to kilometers scale in a Viking or Mariner image, then it will appear smooth at the meter-scale in a MOC image. (2) If the terrain appears to be smooth in the Viking or Mariner image, it will be rough in the meter-scale MOC image. The image pair above illustrates the first "rule." MOC2-137a (left) shows a rugged plain in the martian southern cratered highlands near the Nepenthes Mensae. The small white box indicates the location of the MOC image, which is on the right (MOC2-137b). The MOC image reveals that while the terrain is rough at the large scale, it is quite smooth at the meter-scale. The Viking image shown here is illuminated from the upper right, while the MOC image is illuminated from the upper left. The MOC image was taken in April 1999, while the Viking image was obtained in the late 1970s. More details about this work are provided in an extended abstract (in Acrobat® PDF format) by M.C. Malin, K. S. Edgett, and T. J. Parker, "Characterization of terrain in the Mars Surveyor 2001 landing site latitude and elevation region using Mapping Phase Mars Global Surveyor MOC images," [ http://www.msss.com/mars/global_surveyor/camera/images/6_25_99_landingsites/malin_buffalo_abs.pdf ], presented at the Second Mars Surveyor Landing Site Workshop, held June 22-23, 1999, in Buffalo, New York. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

Evidence for Recent Liquid Water on Mars: Gullies in Crater Wall, Noachis Terra

Evidence for Recent Liquid W …

PIA01035

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Gullies in Crater Wall, Noachis Terra
Original Caption Released with Image	Gullies eroded into the wall of a meteor impact crater in Noachis Terra. This high resolution view (top left) from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) shows channels and associated aprons of debris that are interpreted to have formed by groundwater seepage, surface runoff, and debris flow. The lack of small craters superimposed on the channels and apron deposits indicates that these features are geologically young. It is possible that these gullies indicate that liquid water is present within the martian subsurface today. The MOC image was acquired on September 28, 1999. The scene covers an area approximately 3 kilometers (1.9 miles) wide by 6.7 km (4.1 mi) high (note, the aspect ratio is 1.5 to 1.0). Sunlight illuminates this area from the upper left. The image is located near 54.8°S, 342.5°W. The context image (above) shows the location of the MOC image on the south-facing wall of an impact crater approximately 20 kilometers (12 miles) in diameter. The context picture was obtained by the Viking 1 orbiter in 1980 and is illuminated from the upper left. The large mound on the floor of the crater in the context view is a sand dune field. The Mars Orbiter Camera high resolution images are taken black-and-white (grayscale), the color seen here has been synthesized from the colors of Mars observed by the MOC wide angle cameras and by the Viking Orbiters in the late 1970s. A brief description of how the color was generated:"The MOC narrow angle camera only takes grayscale (black and white) pictures. To create the color versions seen here, we have taken much lower resolution red and blue images acquired by the MOC's wide angle cameras, and by the Viking Orbiter cameras in the 1970s, synthesized a green image by averaging red and blue, and created a pallette of colors that represent the range of colors on Mars. We then use a relationship that correlates color and brightness to assign a color to each gray level. This only a crude approximation of martian color and should only be considered representative of Mars. It is likely Mars would not look like this to a human observer at Mars. "

Evidence for Recent Liquid W …

PIA01035

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Gullies in Crater Wall, Noachis Terra
Original Caption Released with Image	Gullies eroded into the wall of a meteor impact crater in Noachis Terra. This high resolution view (top left) from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) shows channels and associated aprons of debris that are interpreted to have formed by groundwater seepage, surface runoff, and debris flow. The lack of small craters superimposed on the channels and apron deposits indicates that these features are geologically young. It is possible that these gullies indicate that liquid water is present within the martian subsurface today. The MOC image was acquired on September 28, 1999. The scene covers an area approximately 3 kilometers (1.9 miles) wide by 6.7 km (4.1 mi) high (note, the aspect ratio is 1.5 to 1.0). Sunlight illuminates this area from the upper left. The image is located near 54.8°S, 342.5°W. The context image (above) shows the location of the MOC image on the south-facing wall of an impact crater approximately 20 kilometers (12 miles) in diameter. The context picture was obtained by the Viking 1 orbiter in 1980 and is illuminated from the upper left. The large mound on the floor of the crater in the context view is a sand dune field. The Mars Orbiter Camera high resolution images are taken black-and-white (grayscale), the color seen here has been synthesized from the colors of Mars observed by the MOC wide angle cameras and by the Viking Orbiters in the late 1970s. A brief description of how the color was generated:"The MOC narrow angle camera only takes grayscale (black and white) pictures. To create the color versions seen here, we have taken much lower resolution red and blue images acquired by the MOC's wide angle cameras, and by the Viking Orbiter cameras in the 1970s, synthesized a green image by averaging red and blue, and created a pallette of colors that represent the range of colors on Mars. We then use a relationship that correlates color and brightness to assign a color to each gray level. This only a crude approximation of martian color and should only be considered representative of Mars. It is likely Mars would not look like this to a human observer at Mars. "

Evidence for Recent Liquid W …

PIA01035

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Gullies in Crater Wall, Noachis Terra
Original Caption Released with Image	Gullies eroded into the wall of a meteor impact crater in Noachis Terra. This high resolution view (top left) from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) shows channels and associated aprons of debris that are interpreted to have formed by groundwater seepage, surface runoff, and debris flow. The lack of small craters superimposed on the channels and apron deposits indicates that these features are geologically young. It is possible that these gullies indicate that liquid water is present within the martian subsurface today. The MOC image was acquired on September 28, 1999. The scene covers an area approximately 3 kilometers (1.9 miles) wide by 6.7 km (4.1 mi) high (note, the aspect ratio is 1.5 to 1.0). Sunlight illuminates this area from the upper left. The image is located near 54.8°S, 342.5°W. The context image (above) shows the location of the MOC image on the south-facing wall of an impact crater approximately 20 kilometers (12 miles) in diameter. The context picture was obtained by the Viking 1 orbiter in 1980 and is illuminated from the upper left. The large mound on the floor of the crater in the context view is a sand dune field. The Mars Orbiter Camera high resolution images are taken black-and-white (grayscale), the color seen here has been synthesized from the colors of Mars observed by the MOC wide angle cameras and by the Viking Orbiters in the late 1970s. A brief description of how the color was generated:"The MOC narrow angle camera only takes grayscale (black and white) pictures. To create the color versions seen here, we have taken much lower resolution red and blue images acquired by the MOC's wide angle cameras, and by the Viking Orbiter cameras in the 1970s, synthesized a green image by averaging red and blue, and created a pallette of colors that represent the range of colors on Mars. We then use a relationship that correlates color and brightness to assign a color to each gray level. This only a crude approximation of martian color and should only be considered representative of Mars. It is likely Mars would not look like this to a human observer at Mars. "

Proposed Mars Polar Lander Landing Site (Global Perspective)

Proposed Mars Polar Lander L …

PIA02315

Sol (our sun)

Title	Proposed Mars Polar Lander Landing Site (Global Perspective)
Original Caption Released with Image	A mosaic of 24 images taken on a single northern summer day in April 1999 are stitched together to create a global view of Mars. We rotate the planet to reveal the South Pole. Viking data is used to fill in some of this region which is in darkness during this season. The landing site is located at latitude 76degrees South, longitude 195 degrees West. A bright blue ellipse indicates the landing location of the landing site. The ellipse is 5 kilometers wide and 90 kilometers long. Launched Jan. 3, Mars Polar Lander will set down gently on the Red Planet Dec. 3 for the start of a three-month mission to help scientists study the planet's climate history. Polar Lander was launched toward a Colorado-sized area at about 75 degrees south latitude on Mars. Mission planners have been reviewing images and three-dimensional topographic measurements from NASA's orbiting Mars Global Surveyor mission to pick a safe and scientifically interesting spot to land. Piggybacking on the Polar Lander are two basketball-sized aeroshells containing the Deep Space 2 microprobes. Part of NASA's New Millennium program, which tests risky new technologies for future science missions, these two grapefruit-sized penetrators will smash into Mars at about 400 mph and search for signs of water ice about 3 feet below the surface. Mars Polar Lander and its companion mission, the Mars Climate Orbiter, make up the second wave of spacecraft in the long-term Mars Surveyor Program, which is managed by the Jet Propulsion Laboratory for NASA's Office of Space Science. JPL's industrial partner in the development and operation of the Mars Global Surveyor, Polar Lander, and Climate Orbiter spacecraft is Lockheed Martin Astronautics, Denver, CO. JPL is a division of the California Institute of Technology, Pasadena, CA. For additional information about the Mars Surveyor 1998 Project, please visit our website at:http://mars.jpl.nasa.gov/msp98/lander/launch.html [ http://mars.jpl.nasa.gov/msp98/lander/launch.html ] To view additional MOC images, please visit the MSSS website at http://www.msss.com For additional information on MOLA, please visit our website at: http://ltpwww.gsfc.nasa.gov/tharsis/98lander.html [ http://ltpwww.gsfc.nasa.gov/tharsis/98lander.html ]

A Closer Encounter with Mars

Title	A Closer Encounter with Mars

Mars and Acidalia

Title	Mars and Acidalia
Full Description	Taking advantage of Mars's closest approach to Earth in eight years, astronomers using NASA's Hubble Space Telescope have taken the space- based observatory's sharpest views yet of the Red Planet. The telescope's Wide Field and Planetary Camera 2 snapped these images between April 27 and May 6, when Mars was 54 million miles (87 million kilometers) from Earth. From this distance the telescope could see Martian features as small as 12 miles (19 kilometers) wide. The telescope obtained four images, which, together, show the entire planet. Each view depicts the planet as it completes one quarter of its daily rotation. In these views the north polar cap is tilted toward the Earth and is visible prominently at the top of each picture. The images were taken in the middle of the Martian northern summer, when the polar cap had shrunk to its smallest size. During this season the Sun shines continuously on the polar cap. Previous telescopic and spacecraft observations have shown that this summertime "residual" polar cap is composed of water ice, just like Earth's polar caps. These Hubble telescope snapshots reveal that substantial changes in the bright and dark markings on Mars have occurred in the 20 years since the NASA Viking spacecraft missions first mapped the planet. The Martian surface is dynamic and ever changing. Some regions that were dark 20 years ago are now bright red, some areas that were bright red are now dark. Winds move sand and dust from region to region, often in spectacular dust storms. Over long timescales many of the larger bright and dark markings remain stable, but smaller details come and go as they are covered and then uncovered by sand and dust. This image is centered near the location of the Pathfinder landing site. Dark sand dunes that surround the polar cap merge into a large, dark region called Acidalia. This area, as shown by images from the Hubble telescope and other spacecraft, is composed of dark, sand-sized grains of pulverized volcanic rock. Below and to the left of Acidalia are the massive Martian canyon systems of Valles Marineris, some of which form long linear markings that were once thought by some to be canals. Early morning clouds can be seen along the left limb of the planet, and a large cyclonic storm composed of water ice is churning near the polar cap.
Date	06/30/1999
NASA Center	Hubble Space Telescope Center

Mars and Elysium

Title	Mars and Elysium
Full Description	Taking advantage of Mars's closest approach to Earth in eight years, astronomers using NASA's Hubble Space Telescope have taken the space- based observatory's sharpest views yet of the Red Planet. The telescope's Wide Field and Planetary Camera 2 snapped these images between April 27 and May 6, when Mars was 54 million miles (87 million kilometers) from Earth. From this distance the telescope could see Martian features as small as 12 miles (19 kilometers) wide. The telescope obtained these four images, which, together, show the entire planet. Each view depicts the planet as it completes one quarter of its daily rotation. In these views the north polar cap is tilted toward the Earth and is visible prominently at the top of each picture. The images were taken in the middle of the Martian northern summer, when the polar cap had shrunk to its smallest size. During this season the Sun shines continuously on the polar cap. Previous telescopic and spacecraft observations have shown that this summertime "residual" polar cap is composed of water ice, just like Earth's polar caps. These Hubble telescope snapshots reveal that substantial changes in the bright and dark markings on Mars have occurred in the 20 years since the NASA Viking spacecraft missions first mapped the planet. The Martian surface is dynamic and ever changing. Some regions that were dark 20 years ago are now bright red, some areas that were bright red are now dark. Winds move sand and dust from region to region, often in spectacular dust storms. Over long timescales many of the larger bright and dark markings remain stable, but smaller details come and go as they are covered and then uncovered by sand and dust. This image is centered near another volcanic region known as Elysium. This area shows many small, dark markings that have been observed by the Hubble telescope and other spacecraft to change as a result of the movement of sand and dust across the Martian surface. In the upper left of this image, at high northern latitudes, a large chevron-shaped area of water ice clouds mark a storm front. Along the right limb, a large cloud system has formed around the Olympus Mons volcano.
Date	06/30/1999
NASA Center	Hubble Space Telescope Center

Mars and Tharsis

Title	Mars and Tharsis
Full Description	Taking advantage of Mars's closest approach to Earth in eight years, astronomers using NASA's Hubble Space Telescope have taken the space- based observatory's sharpest views yet of the Red Planet. The telescope's Wide Field and Planetary Camera 2 snapped these images between April 27 and May 6, when Mars was 54 million miles (87 million kilometers) from Earth. From this distance the telescope could see Martian features as small as 12 miles (19 kilometers) wide. The telescope obtained four images, which together show the entire planet. Each view depicts the planet as it completes one quarter of its daily rotation. In these views the north polar cap is tilted toward the Earth and is visible prominently at the top of each picture. The images were taken in the middle of the Martian northern summer, when the polar cap had shrunk to its smallest size. During this season the Sun shines continuously on the polar cap. Previous telescopic and spacecraft observations have shown that this summertime "residual" polar cap is composed of water ice, just like Earth's polar caps. These Hubble telescope snapshots reveal that substantial changes in the bright and dark markings on Mars have occurred in the 20 years since the NASA Viking spacecraft missions first mapped the planet. The Martian surface is dynamic and ever changing. Some regions that were dark 20 years ago are now bright red, some areas that were bright red are now dark. Winds move sand and dust from region to region, often in spectacular dust storms. Over long timescales many of the larger bright and dark markings remain stable, but smaller details come and go as they are covered and then uncovered by sand and dust. This image is centered on the region of the planet known as Tharsis, home of the largest volcanoes in the solar system. The bright, ring- like feature just to the left of center is the volcano Olympus Mons, which is more than 340 miles (550 kilometers) across and 17 miles (27 kilometers) high. Thick deposits of fine-grained, windblown dust cover most of this hemisphere. The colors indicate that the dust is heavily oxidized ("rusted"), and millions (or perhaps billions) of years of dust storms have homogenized its composition. Prominent late afternoon clouds along the right limb of the planet can be seen.
Date	06/30/1999
NASA Center	Hubble Space Telescope Center

Once Pitted, Twice Spied: A New High Resolution View Inside Escalante Crater

Once Pitted, Twice Spied: A …

PIA02007

Sol (our sun)

Mars Orbiter Camera

Title	Once Pitted, Twice Spied: A New High Resolution View Inside Escalante Crater
Original Caption Released with Image	During the year spent waiting to achieve the planned circular, polar Mapping Orbit, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) took about 1170pictures that had resolutions in the 2 to 20 meters (7-66 feet) per pixel range. These pictures were obtained between September 1997 and September 1998, and are now archived with NASA and available to the public at NASAPDS--http://ida.wr.usgs.gov/ [ http://ida.wr.usgs.gov/ ] . Although these pictures were generally a vast improvement in spatial resolution compared to the previous images from Viking and Mariner, the latest pictures from MOC--taken this month (April 1999) from the proper Mapping Orbit--demonstrate the power of the MOC when in focus and operating at the correct altitude (~380 km or 235 miles). The Viking Orbiter picture on the left, above, shows the 83 kilometers-(52 miles)-wide crater, Escalante. Located on the martian equator at 245°W longitude, a portion of this crater's floor was seen by MOC before the mapping mission began, at a resolution of 9.4 meters (31 feet) per pixel as shown in the middle image. The new picture--on the right--peers down into one of the pits seen in the earlier MOC image--only now it is viewed at 1.8 meters (6 feet) per pixel. The new high resolution image (right) covers an area only 1.5 kilometers (0.9 miles)wide and shows that the crater floor--which appears relatively smooth in the context view on the left--is actually quite rough at the scale that a human being would notice if trying to hike around in this landscape. The latest picture also shows small, bright windblown dunes that were not visible in the earlier MOC image. MOC2-120a is a mosaic of Viking Orbiter images 381s62 and 379s47, and MOC2-120b is a subframe of MGS MOC image SPO-2-382/04. The large white box shows the location of MOC2-120b, and the small white box shows the location of MOC2-120c. In MOC2-120a and MOC2-120b, illumination is from the right/upper right, in MOC2-120c it is from the left. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

Once Pitted, Twice Spied: A …

PIA02007

Sol (our sun)

Mars Orbiter Camera

Title	Once Pitted, Twice Spied: A New High Resolution View Inside Escalante Crater
Original Caption Released with Image	During the year spent waiting to achieve the planned circular, polar Mapping Orbit, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) took about 1170pictures that had resolutions in the 2 to 20 meters (7-66 feet) per pixel range. These pictures were obtained between September 1997 and September 1998, and are now archived with NASA and available to the public at NASAPDS--http://ida.wr.usgs.gov/ [ http://ida.wr.usgs.gov/ ] . Although these pictures were generally a vast improvement in spatial resolution compared to the previous images from Viking and Mariner, the latest pictures from MOC--taken this month (April 1999) from the proper Mapping Orbit--demonstrate the power of the MOC when in focus and operating at the correct altitude (~380 km or 235 miles). The Viking Orbiter picture on the left, above, shows the 83 kilometers-(52 miles)-wide crater, Escalante. Located on the martian equator at 245°W longitude, a portion of this crater's floor was seen by MOC before the mapping mission began, at a resolution of 9.4 meters (31 feet) per pixel as shown in the middle image. The new picture--on the right--peers down into one of the pits seen in the earlier MOC image--only now it is viewed at 1.8 meters (6 feet) per pixel. The new high resolution image (right) covers an area only 1.5 kilometers (0.9 miles)wide and shows that the crater floor--which appears relatively smooth in the context view on the left--is actually quite rough at the scale that a human being would notice if trying to hike around in this landscape. The latest picture also shows small, bright windblown dunes that were not visible in the earlier MOC image. MOC2-120a is a mosaic of Viking Orbiter images 381s62 and 379s47, and MOC2-120b is a subframe of MGS MOC image SPO-2-382/04. The large white box shows the location of MOC2-120b, and the small white box shows the location of MOC2-120c. In MOC2-120a and MOC2-120b, illumination is from the right/upper right, in MOC2-120c it is from the left. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

Once Pitted, Twice Spied: A …

PIA02007

Sol (our sun)

Mars Orbiter Camera

Title	Once Pitted, Twice Spied: A New High Resolution View Inside Escalante Crater
Original Caption Released with Image	During the year spent waiting to achieve the planned circular, polar Mapping Orbit, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) took about 1170pictures that had resolutions in the 2 to 20 meters (7-66 feet) per pixel range. These pictures were obtained between September 1997 and September 1998, and are now archived with NASA and available to the public at NASAPDS--http://ida.wr.usgs.gov/ [ http://ida.wr.usgs.gov/ ] . Although these pictures were generally a vast improvement in spatial resolution compared to the previous images from Viking and Mariner, the latest pictures from MOC--taken this month (April 1999) from the proper Mapping Orbit--demonstrate the power of the MOC when in focus and operating at the correct altitude (~380 km or 235 miles). The Viking Orbiter picture on the left, above, shows the 83 kilometers-(52 miles)-wide crater, Escalante. Located on the martian equator at 245°W longitude, a portion of this crater's floor was seen by MOC before the mapping mission began, at a resolution of 9.4 meters (31 feet) per pixel as shown in the middle image. The new picture--on the right--peers down into one of the pits seen in the earlier MOC image--only now it is viewed at 1.8 meters (6 feet) per pixel. The new high resolution image (right) covers an area only 1.5 kilometers (0.9 miles)wide and shows that the crater floor--which appears relatively smooth in the context view on the left--is actually quite rough at the scale that a human being would notice if trying to hike around in this landscape. The latest picture also shows small, bright windblown dunes that were not visible in the earlier MOC image. MOC2-120a is a mosaic of Viking Orbiter images 381s62 and 379s47, and MOC2-120b is a subframe of MGS MOC image SPO-2-382/04. The large white box shows the location of MOC2-120b, and the small white box shows the location of MOC2-120c. In MOC2-120a and MOC2-120b, illumination is from the right/upper right, in MOC2-120c it is from the left. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

Once Pitted, Twice Spied: A …

PIA02007

Sol (our sun)

Mars Orbiter Camera

Title	Once Pitted, Twice Spied: A New High Resolution View Inside Escalante Crater
Original Caption Released with Image	During the year spent waiting to achieve the planned circular, polar Mapping Orbit, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) took about 1170pictures that had resolutions in the 2 to 20 meters (7-66 feet) per pixel range. These pictures were obtained between September 1997 and September 1998, and are now archived with NASA and available to the public at NASAPDS--http://ida.wr.usgs.gov/ [ http://ida.wr.usgs.gov/ ] . Although these pictures were generally a vast improvement in spatial resolution compared to the previous images from Viking and Mariner, the latest pictures from MOC--taken this month (April 1999) from the proper Mapping Orbit--demonstrate the power of the MOC when in focus and operating at the correct altitude (~380 km or 235 miles). The Viking Orbiter picture on the left, above, shows the 83 kilometers-(52 miles)-wide crater, Escalante. Located on the martian equator at 245°W longitude, a portion of this crater's floor was seen by MOC before the mapping mission began, at a resolution of 9.4 meters (31 feet) per pixel as shown in the middle image. The new picture--on the right--peers down into one of the pits seen in the earlier MOC image--only now it is viewed at 1.8 meters (6 feet) per pixel. The new high resolution image (right) covers an area only 1.5 kilometers (0.9 miles)wide and shows that the crater floor--which appears relatively smooth in the context view on the left--is actually quite rough at the scale that a human being would notice if trying to hike around in this landscape. The latest picture also shows small, bright windblown dunes that were not visible in the earlier MOC image. MOC2-120a is a mosaic of Viking Orbiter images 381s62 and 379s47, and MOC2-120b is a subframe of MGS MOC image SPO-2-382/04. The large white box shows the location of MOC2-120b, and the small white box shows the location of MOC2-120c. In MOC2-120a and MOC2-120b, illumination is from the right/upper right, in MOC2-120c it is from the left. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

MOC's 200,000th Image

PIA07995

Sol (our sun)

Mars Orbiter Camera

Title	MOC's 200,000th Image
Original Caption Released with Image	3 June 2005 On 17 May 2005, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) acquired its 200,000th image since the spacecraft began orbiting Mars on 12 September 1997. This image shows details on the floor and in the ejecta blanket of a northern middle-latitude martian crater, was received on Earth the following day. Its red wide angle context frame was also acquired at the same time (see PIA07996 [ http://photojournal.jpl.nasa.gov/catalog/PIA07996 ]). This image marks a milestone for the Mars Global Surveyor mission, which has returned nearly four times the number of images of both the Viking 1 and Viking 2 orbiters, combined, in the late 1970s. An additional point of comparison, the two Viking camera systems returned about 70 Gbytes of data, MOC thus far has returned 365 Gbytes (after decompression). The MOC is really a system consisting of three cameras: (1) a narrow angle camera, essentially a telescope, that obtains extremely high resolution views ranging from about 0.5 to about 14 meters per pixel, (2) a red wide angle camera that is used to take context images, daily global maps, and other selected images, and (3) a blue wide angle camera that also acquires daily global maps, views of the martian limb, and other selected targets. Both wide angle cameras can obtain images with resolutions in the range of 0.24 to 7.5 kilometers per pixel. The first images acquired by MOC were taken during the third orbit of MGS on 15 September 1997. MGS conducted a pre-mission series of observations between mid-September 1997 and February 1999. Then, MGS conducted its 1 Mars year Primary Mission from March 1999 through January 2001. The Extended Mission phase for MGS began in February 2001 and continues to this day. "Location near": 32.7°N, 185.1°W "Image width": ~3 km (~1.9 mi) "Illumination from": lower left "Season": Northern Autumn

MOC's 200,001st Image

PIA07996

Sol (our sun)

Mars Orbiter Camera

Title	MOC's 200,001st Image
Original Caption Released with Image	3 June 2005 On 17 May 2005, the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) acquired its 200,000th image since the spacecraft began orbiting Mars on 12 September 1997. This red wide angle context frame was acquired at the same time as the narrow angle image (see PIA07995 [ http://photojournal.jpl.nasa.gov/catalog/PIA07995 ] showing details on the floor and in the ejecta blanket of a northern middle-latitude martian crater, which was received on Earth the previous day). This image marks a milestone for the Mars Global Surveyor mission, which has returned nearly four times the number of images of both the Viking 1 and Viking 2 orbiters, combined, in the late 1970s. An additional point of comparison, the two Viking camera systems returned about 70 Gbytes of data, MOC thus far has returned 365 Gbytes (after decompression). The MOC is really a system consisting of three cameras: (1) a narrow angle camera, essentially a telescope, that obtains extremely high resolution views ranging from about 0.5 to about 14 meters per pixel, (2) a red wide angle camera that is used to take context images, daily global maps, and other selected images, and (3) a blue wide angle camera that also acquires daily global maps, views of the martian limb, and other selected targets. Both wide angle cameras can obtain images with resolutions in the range of 0.24 to 7.5 kilometers per pixel. The first images acquired by MOC were taken during the third orbit of MGS on 15 September 1997. MGS conducted a pre-mission series of observations between mid-September 1997 and February 1999. Then, MGS conducted its 1 Mars year Primary Mission from March 1999 through January 2001. The Extended Mission phase for MGS began in February 2001 and continues to this day. "Location near": 32.7°N, 185.1°W "Image width": ~115 km (~71 mi) "Illumination from": lower left "Season": Northern Autumn

New Cydonia Picture

PIA02092

Sol (our sun)

Mars Orbiter Camera

Title	New Cydonia Picture
Original Caption Released with Image	The Mars Orbiter Camera (MOC) onboard the Mars Global Surveyor (MGS) orbiter, was designed specifically to bridge the gap between what can be seen from orbit in typical Mariner 9 and Viking orbiter images, and what can be seen from the ground by landers such as Viking 1 and Mars Pathfinder. The camera, therefore, takes pictures of extremely high resolution. These images are often comparable to aerial photographs used by geologists when they are exploring Earth. The highest resolution images that can be obtained are in the range of 1.4 to 2.0 meters (4.6 to 6.5 feet) per pixel. Last year, several pictures of a portion of the Cydonia region of Mars were photographed at lower resolution than is now possible in the Mapping Phase of the MGS mission. The Cydonia region is perhaps most "famous" for being the location of a feature that--in Viking Orbiter images--seemed to resemble a human face. Nearby buttes and hills were considered by some to represent a "city." The MGS spacecraft flew over the "famous" Cydonia landforms again--for the first time since April 1998--on June 27, 1999, at 10:53 UTC (Greenwich Time Zone). The new MOC images shown here provide the highest resolution view yet obtained of the "Cydonia city" landforms. The picture at the above left (MOC2-142a), shows the regional context. Cydonia constitutes a transition zone between the cratered highlands of Arabia Terra, and the less-cratered lowlands of Acidalia Planitia. This transition zone contains thousands of mesas and buttes--somewhat like the Monument Valley region along the Arizona/Utah border in North America. The white box shows the location of the new high resolution view of the "city" landforms. The image is a red wide angle context frame obtained by MOC at the same time that the high resolution view was acquired. The picture is illuminated from the lower left, and north is toward the upper right. The picture in the center is a processed version of the new MOC narrow angle camera image of this portion of Cydonia. You can view the full-size image Like the context image (above left), the high resolution view (center) is illuminated from the lower left. North is toward the upper right. Boulders can be seen on some of the hill slopes, and the plains between the hills are rough and pitted. To conserve data in order to account for downtrack position uncertainties, only 1/2 of the MOC sensor was used to acquire this picture (allowing the image to be twice the length): it covers an area that is 1.5 km (0.9 mi) wide. The picture at the above right is the unprocessed MOC image. This what the processed image (center) looked like before it was rotated 180° (so that north is toward the top) and corrected for a 1.5 aspect ratio. The pixel size in the unprocessed image is different in the cross-track (left-right) and down-track(top-bottom) directions, thus making the craters look "squished." The cross-track scale is about 1.5 meters (5 feet) per pixel, while the down-track scale is about 2.25 meters (7.4 feet) per pixel. In the unprocessed image, the illumination is coming from the upper right. You can view this image at full-size (use "Save this link as..." and examine (MOC2-142c 100% Size) or see it via your web-browser at half-size (MOC2-142c 50% Size). For a look at the Cydonia images previously obtained by MGS MOC in 1998, CLICKHERE [ http://www.msss.com/mars/global_surveyor/camera/images/MENUS/cydonia_list.html ]. For a pre-MGS discussion of Viking orbiter images of the "Face on Mars,"CLICKHERE [ http://www.msss.com/education/facepage/face.html ]. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

New Cydonia Picture

PIA02092

Sol (our sun)

Mars Orbiter Camera

Title	New Cydonia Picture
Original Caption Released with Image	The Mars Orbiter Camera (MOC) onboard the Mars Global Surveyor (MGS) orbiter, was designed specifically to bridge the gap between what can be seen from orbit in typical Mariner 9 and Viking orbiter images, and what can be seen from the ground by landers such as Viking 1 and Mars Pathfinder. The camera, therefore, takes pictures of extremely high resolution. These images are often comparable to aerial photographs used by geologists when they are exploring Earth. The highest resolution images that can be obtained are in the range of 1.4 to 2.0 meters (4.6 to 6.5 feet) per pixel. Last year, several pictures of a portion of the Cydonia region of Mars were photographed at lower resolution than is now possible in the Mapping Phase of the MGS mission. The Cydonia region is perhaps most "famous" for being the location of a feature that--in Viking Orbiter images--seemed to resemble a human face. Nearby buttes and hills were considered by some to represent a "city." The MGS spacecraft flew over the "famous" Cydonia landforms again--for the first time since April 1998--on June 27, 1999, at 10:53 UTC (Greenwich Time Zone). The new MOC images shown here provide the highest resolution view yet obtained of the "Cydonia city" landforms. The picture at the above left (MOC2-142a), shows the regional context. Cydonia constitutes a transition zone between the cratered highlands of Arabia Terra, and the less-cratered lowlands of Acidalia Planitia. This transition zone contains thousands of mesas and buttes--somewhat like the Monument Valley region along the Arizona/Utah border in North America. The white box shows the location of the new high resolution view of the "city" landforms. The image is a red wide angle context frame obtained by MOC at the same time that the high resolution view was acquired. The picture is illuminated from the lower left, and north is toward the upper right. The picture in the center is a processed version of the new MOC narrow angle camera image of this portion of Cydonia. You can view the full-size image Like the context image (above left), the high resolution view (center) is illuminated from the lower left. North is toward the upper right. Boulders can be seen on some of the hill slopes, and the plains between the hills are rough and pitted. To conserve data in order to account for downtrack position uncertainties, only 1/2 of the MOC sensor was used to acquire this picture (allowing the image to be twice the length): it covers an area that is 1.5 km (0.9 mi) wide. The picture at the above right is the unprocessed MOC image. This what the processed image (center) looked like before it was rotated 180° (so that north is toward the top) and corrected for a 1.5 aspect ratio. The pixel size in the unprocessed image is different in the cross-track (left-right) and down-track(top-bottom) directions, thus making the craters look "squished." The cross-track scale is about 1.5 meters (5 feet) per pixel, while the down-track scale is about 2.25 meters (7.4 feet) per pixel. In the unprocessed image, the illumination is coming from the upper right. You can view this image at full-size (use "Save this link as..." and examine (MOC2-142c 100% Size) or see it via your web-browser at half-size (MOC2-142c 50% Size). For a look at the Cydonia images previously obtained by MGS MOC in 1998, CLICKHERE [ http://www.msss.com/mars/global_surveyor/camera/images/MENUS/cydonia_list.html ]. For a pre-MGS discussion of Viking orbiter images of the "Face on Mars,"CLICKHERE [ http://www.msss.com/education/facepage/face.html ]. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

New Cydonia Picture

PIA02092

Sol (our sun)

Mars Orbiter Camera

Title	New Cydonia Picture
Original Caption Released with Image	The Mars Orbiter Camera (MOC) onboard the Mars Global Surveyor (MGS) orbiter, was designed specifically to bridge the gap between what can be seen from orbit in typical Mariner 9 and Viking orbiter images, and what can be seen from the ground by landers such as Viking 1 and Mars Pathfinder. The camera, therefore, takes pictures of extremely high resolution. These images are often comparable to aerial photographs used by geologists when they are exploring Earth. The highest resolution images that can be obtained are in the range of 1.4 to 2.0 meters (4.6 to 6.5 feet) per pixel. Last year, several pictures of a portion of the Cydonia region of Mars were photographed at lower resolution than is now possible in the Mapping Phase of the MGS mission. The Cydonia region is perhaps most "famous" for being the location of a feature that--in Viking Orbiter images--seemed to resemble a human face. Nearby buttes and hills were considered by some to represent a "city." The MGS spacecraft flew over the "famous" Cydonia landforms again--for the first time since April 1998--on June 27, 1999, at 10:53 UTC (Greenwich Time Zone). The new MOC images shown here provide the highest resolution view yet obtained of the "Cydonia city" landforms. The picture at the above left (MOC2-142a), shows the regional context. Cydonia constitutes a transition zone between the cratered highlands of Arabia Terra, and the less-cratered lowlands of Acidalia Planitia. This transition zone contains thousands of mesas and buttes--somewhat like the Monument Valley region along the Arizona/Utah border in North America. The white box shows the location of the new high resolution view of the "city" landforms. The image is a red wide angle context frame obtained by MOC at the same time that the high resolution view was acquired. The picture is illuminated from the lower left, and north is toward the upper right. The picture in the center is a processed version of the new MOC narrow angle camera image of this portion of Cydonia. You can view the full-size image Like the context image (above left), the high resolution view (center) is illuminated from the lower left. North is toward the upper right. Boulders can be seen on some of the hill slopes, and the plains between the hills are rough and pitted. To conserve data in order to account for downtrack position uncertainties, only 1/2 of the MOC sensor was used to acquire this picture (allowing the image to be twice the length): it covers an area that is 1.5 km (0.9 mi) wide. The picture at the above right is the unprocessed MOC image. This what the processed image (center) looked like before it was rotated 180° (so that north is toward the top) and corrected for a 1.5 aspect ratio. The pixel size in the unprocessed image is different in the cross-track (left-right) and down-track(top-bottom) directions, thus making the craters look "squished." The cross-track scale is about 1.5 meters (5 feet) per pixel, while the down-track scale is about 2.25 meters (7.4 feet) per pixel. In the unprocessed image, the illumination is coming from the upper right. You can view this image at full-size (use "Save this link as..." and examine (MOC2-142c 100% Size) or see it via your web-browser at half-size (MOC2-142c 50% Size). For a look at the Cydonia images previously obtained by MGS MOC in 1998, CLICKHERE [ http://www.msss.com/mars/global_surveyor/camera/images/MENUS/cydonia_list.html ]. For a pre-MGS discussion of Viking orbiter images of the "Face on Mars,"CLICKHERE [ http://www.msss.com/education/facepage/face.html ]. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

New Cydonia Picture

PIA02092

Sol (our sun)

Mars Orbiter Camera

Title	New Cydonia Picture
Original Caption Released with Image	The Mars Orbiter Camera (MOC) onboard the Mars Global Surveyor (MGS) orbiter, was designed specifically to bridge the gap between what can be seen from orbit in typical Mariner 9 and Viking orbiter images, and what can be seen from the ground by landers such as Viking 1 and Mars Pathfinder. The camera, therefore, takes pictures of extremely high resolution. These images are often comparable to aerial photographs used by geologists when they are exploring Earth. The highest resolution images that can be obtained are in the range of 1.4 to 2.0 meters (4.6 to 6.5 feet) per pixel. Last year, several pictures of a portion of the Cydonia region of Mars were photographed at lower resolution than is now possible in the Mapping Phase of the MGS mission. The Cydonia region is perhaps most "famous" for being the location of a feature that--in Viking Orbiter images--seemed to resemble a human face. Nearby buttes and hills were considered by some to represent a "city." The MGS spacecraft flew over the "famous" Cydonia landforms again--for the first time since April 1998--on June 27, 1999, at 10:53 UTC (Greenwich Time Zone). The new MOC images shown here provide the highest resolution view yet obtained of the "Cydonia city" landforms. The picture at the above left (MOC2-142a), shows the regional context. Cydonia constitutes a transition zone between the cratered highlands of Arabia Terra, and the less-cratered lowlands of Acidalia Planitia. This transition zone contains thousands of mesas and buttes--somewhat like the Monument Valley region along the Arizona/Utah border in North America. The white box shows the location of the new high resolution view of the "city" landforms. The image is a red wide angle context frame obtained by MOC at the same time that the high resolution view was acquired. The picture is illuminated from the lower left, and north is toward the upper right. The picture in the center is a processed version of the new MOC narrow angle camera image of this portion of Cydonia. You can view the full-size image Like the context image (above left), the high resolution view (center) is illuminated from the lower left. North is toward the upper right. Boulders can be seen on some of the hill slopes, and the plains between the hills are rough and pitted. To conserve data in order to account for downtrack position uncertainties, only 1/2 of the MOC sensor was used to acquire this picture (allowing the image to be twice the length): it covers an area that is 1.5 km (0.9 mi) wide. The picture at the above right is the unprocessed MOC image. This what the processed image (center) looked like before it was rotated 180° (so that north is toward the top) and corrected for a 1.5 aspect ratio. The pixel size in the unprocessed image is different in the cross-track (left-right) and down-track(top-bottom) directions, thus making the craters look "squished." The cross-track scale is about 1.5 meters (5 feet) per pixel, while the down-track scale is about 2.25 meters (7.4 feet) per pixel. In the unprocessed image, the illumination is coming from the upper right. You can view this image at full-size (use "Save this link as..." and examine (MOC2-142c 100% Size) or see it via your web-browser at half-size (MOC2-142c 50% Size). For a look at the Cydonia images previously obtained by MGS MOC in 1998, CLICKHERE [ http://www.msss.com/mars/global_surveyor/camera/images/MENUS/cydonia_list.html ]. For a pre-MGS discussion of Viking orbiter images of the "Face on Mars,"CLICKHERE [ http://www.msss.com/education/facepage/face.html ]. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

New Cydonia Picture

PIA02092

Sol (our sun)

Mars Orbiter Camera

Title	New Cydonia Picture
Original Caption Released with Image	The Mars Orbiter Camera (MOC) onboard the Mars Global Surveyor (MGS) orbiter, was designed specifically to bridge the gap between what can be seen from orbit in typical Mariner 9 and Viking orbiter images, and what can be seen from the ground by landers such as Viking 1 and Mars Pathfinder. The camera, therefore, takes pictures of extremely high resolution. These images are often comparable to aerial photographs used by geologists when they are exploring Earth. The highest resolution images that can be obtained are in the range of 1.4 to 2.0 meters (4.6 to 6.5 feet) per pixel. Last year, several pictures of a portion of the Cydonia region of Mars were photographed at lower resolution than is now possible in the Mapping Phase of the MGS mission. The Cydonia region is perhaps most "famous" for being the location of a feature that--in Viking Orbiter images--seemed to resemble a human face. Nearby buttes and hills were considered by some to represent a "city." The MGS spacecraft flew over the "famous" Cydonia landforms again--for the first time since April 1998--on June 27, 1999, at 10:53 UTC (Greenwich Time Zone). The new MOC images shown here provide the highest resolution view yet obtained of the "Cydonia city" landforms. The picture at the above left (MOC2-142a), shows the regional context. Cydonia constitutes a transition zone between the cratered highlands of Arabia Terra, and the less-cratered lowlands of Acidalia Planitia. This transition zone contains thousands of mesas and buttes--somewhat like the Monument Valley region along the Arizona/Utah border in North America. The white box shows the location of the new high resolution view of the "city" landforms. The image is a red wide angle context frame obtained by MOC at the same time that the high resolution view was acquired. The picture is illuminated from the lower left, and north is toward the upper right. The picture in the center is a processed version of the new MOC narrow angle camera image of this portion of Cydonia. You can view the full-size image Like the context image (above left), the high resolution view (center) is illuminated from the lower left. North is toward the upper right. Boulders can be seen on some of the hill slopes, and the plains between the hills are rough and pitted. To conserve data in order to account for downtrack position uncertainties, only 1/2 of the MOC sensor was used to acquire this picture (allowing the image to be twice the length): it covers an area that is 1.5 km (0.9 mi) wide. The picture at the above right is the unprocessed MOC image. This what the processed image (center) looked like before it was rotated 180° (so that north is toward the top) and corrected for a 1.5 aspect ratio. The pixel size in the unprocessed image is different in the cross-track (left-right) and down-track(top-bottom) directions, thus making the craters look "squished." The cross-track scale is about 1.5 meters (5 feet) per pixel, while the down-track scale is about 2.25 meters (7.4 feet) per pixel. In the unprocessed image, the illumination is coming from the upper right. You can view this image at full-size (use "Save this link as..." and examine (MOC2-142c 100% Size) or see it via your web-browser at half-size (MOC2-142c 50% Size). For a look at the Cydonia images previously obtained by MGS MOC in 1998, CLICKHERE [ http://www.msss.com/mars/global_surveyor/camera/images/MENUS/cydonia_list.html ]. For a pre-MGS discussion of Viking orbiter images of the "Face on Mars,"CLICKHERE [ http://www.msss.com/education/facepage/face.html ]. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

New Cydonia Picture

PIA02092

Sol (our sun)

Mars Orbiter Camera

Title	New Cydonia Picture
Original Caption Released with Image	The Mars Orbiter Camera (MOC) onboard the Mars Global Surveyor (MGS) orbiter, was designed specifically to bridge the gap between what can be seen from orbit in typical Mariner 9 and Viking orbiter images, and what can be seen from the ground by landers such as Viking 1 and Mars Pathfinder. The camera, therefore, takes pictures of extremely high resolution. These images are often comparable to aerial photographs used by geologists when they are exploring Earth. The highest resolution images that can be obtained are in the range of 1.4 to 2.0 meters (4.6 to 6.5 feet) per pixel. Last year, several pictures of a portion of the Cydonia region of Mars were photographed at lower resolution than is now possible in the Mapping Phase of the MGS mission. The Cydonia region is perhaps most "famous" for being the location of a feature that--in Viking Orbiter images--seemed to resemble a human face. Nearby buttes and hills were considered by some to represent a "city." The MGS spacecraft flew over the "famous" Cydonia landforms again--for the first time since April 1998--on June 27, 1999, at 10:53 UTC (Greenwich Time Zone). The new MOC images shown here provide the highest resolution view yet obtained of the "Cydonia city" landforms. The picture at the above left (MOC2-142a), shows the regional context. Cydonia constitutes a transition zone between the cratered highlands of Arabia Terra, and the less-cratered lowlands of Acidalia Planitia. This transition zone contains thousands of mesas and buttes--somewhat like the Monument Valley region along the Arizona/Utah border in North America. The white box shows the location of the new high resolution view of the "city" landforms. The image is a red wide angle context frame obtained by MOC at the same time that the high resolution view was acquired. The picture is illuminated from the lower left, and north is toward the upper right. The picture in the center is a processed version of the new MOC narrow angle camera image of this portion of Cydonia. You can view the full-size image Like the context image (above left), the high resolution view (center) is illuminated from the lower left. North is toward the upper right. Boulders can be seen on some of the hill slopes, and the plains between the hills are rough and pitted. To conserve data in order to account for downtrack position uncertainties, only 1/2 of the MOC sensor was used to acquire this picture (allowing the image to be twice the length): it covers an area that is 1.5 km (0.9 mi) wide. The picture at the above right is the unprocessed MOC image. This what the processed image (center) looked like before it was rotated 180° (so that north is toward the top) and corrected for a 1.5 aspect ratio. The pixel size in the unprocessed image is different in the cross-track (left-right) and down-track(top-bottom) directions, thus making the craters look "squished." The cross-track scale is about 1.5 meters (5 feet) per pixel, while the down-track scale is about 2.25 meters (7.4 feet) per pixel. In the unprocessed image, the illumination is coming from the upper right. You can view this image at full-size (use "Save this link as..." and examine (MOC2-142c 100% Size) or see it via your web-browser at half-size (MOC2-142c 50% Size). For a look at the Cydonia images previously obtained by MGS MOC in 1998, CLICKHERE [ http://www.msss.com/mars/global_surveyor/camera/images/MENUS/cydonia_list.html ]. For a pre-MGS discussion of Viking orbiter images of the "Face on Mars,"CLICKHERE [ http://www.msss.com/education/facepage/face.html ]. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

Recently-Formed Impact Crate …

title	Recently-Formed Impact Crater
Description	Scientists using the Mars Orbiter Camera on NASA's Mars Global Surveyor spacecraft have discovered a crater that appears to have formed on Mars in the past 20 or so Earth years, and have used it and several other similar craters to estimate the present cratering rate on Mars. One of the basic tenets of planetary geology is that impact craters have accumulated on planetary surfaces at roughly a constant rate since the early history of the solar system. This appears to have been the case for small craters on the surface of the Moon, as shown by measurements of the length of time that lunar rocks created by small impacts have been exposed to cosmic rays, as determined by laboratory measurements of samples returned to Earth by the Apollo astronauts. This principle should permit the number of craters found on a planetary surface to be used to determine the age of that surface, if the rate at which new craters form is known. Scientists have previously estimated the cratering rate of Mars by scaling the lunar cratering rate based on the proximity of Mars to the asteroid belt, and by performing calculations based on orbital mechanics. Another way to establish the cratering rate of Mars would be to use long-term observations, say, from orbiting spacecraft, to actually locate new craters. The new crater is located on the southern rim of the summit crater, or caldera, of the intermediate-sized martian volcano, Ulysses Patera. The site was imaged by the Viking 2 orbiter in 1976 (left, an enlarged portion of the image) and in narrow-angle views by the Mars Orbiter Camera in 1999 (center) and 2005 (right). The new crater, about 25 meters (82 feet) across, is marked by a distinct dark, rayed pattern of ejected material, or ejecta, which is seen to have faded somewhat between 1999 and 2005. Ulysses Patera, a volcanic shield about 100 kilometers (62 miles) in diameter volcanic shield, located near 2.5 degrees north latitude, 121.3 degrees west longitude, is one of the Tharsis volcanoes and is partly buried by younger lava flows. The summit caldera is about 55 kilometers (34 miles) in diameter. The amount that the crater's rays faded between 1999 and 2005 can be used to help estimate how many years ago the crater formed. The actual contrast between the ejecta and the undisturbed volcano summit materials is actually much less than it appears to be in these processed images, and the amount of fading is also much less. Images of disturbed surfaces from various parts of Mars, such as dust devil tracks, dark slope streaks and rover tracks, indicate that disturbed surfaces on Mars are dark and that they lighten with time. Using these other examples to estimate how dark the ejecta from the Ulysses crater was originally, and how much it has faded in six years, suggests the crater formed in the early to mid 1980s. The rate at which dark surfaces lighten on Mars is not uniform over the whole planet, but scientists using the Mars Orbiter Camera have found a number, of other craters with dark ejecta that have faded during the Mars Global Surveyor mission. The scientists estimate that these craters probably formed within the past 100 years. Although the sample is very small (the Mars Orbiter Camera narrow angle camera has imaged barely 4 percent of Mars), it appears that the recent cratering rate for craters on Mars 25 to 100 meters (82 to 328 feet) in diameter is about 0.000000003 to 0.000000006 craters per square kilometer (0.39 square mile) per Earth year, which is about five times lower than previous estimates. The site of the new crater is shown in wider context in a comparison of the 1976 Viking image with wide-angle views taken by the Mars Orbiter Camera in 1999 and 2005 (insert MOC2-1214b), and in even wider context in a regional mosaic of Viking images (insert MOC2-1214c). The Mars Orbiter Camera was built and is operated by Malin Space Science Systems, San Diego, Calif. Mars Global Surveyor left Earth on Nov. 7, 1996, and began orbiting Mars on Sept. 12, 1997. JPL, a division of the California Institute of Technology, Pasadena, manages Mars Global Surveyor for NASA's Science Mission Directorate, Washington. Credit: NASA/JPL/MSSS/USGS

East Gorgonum Crater

title	East Gorgonum Crater
Description	This suite of Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) pictures provides a vista of martian gullies on the northern wall of a 12 kilometer-(7.4 mile)-wide meteor impact crater east of the Gorgonum Chaos region on the red planet. The first picture (lower left) is a composite of three different high resolution MOC views obtained in 1999 and 2000. The second picture (lower right) shows the location of the high resolution views relative to the whole crater as it appeared in the highest resolution image previously acquired of the area, taken by the Viking 1 orbiter in 1978. The release image (top) shows a close-up of one of the channels and debris aprons found in the northwestern quarter of the impact crater. Some of the channels in this crater are deeply-entrenched and cut into lighter-toned deposits. The numerous channels and apron deposits indicate that many tens to hundreds of individual events involving the flow of water and debris have occurred here. The channels and aprons have very crisp, sharp relief and there are no small meteor impact craters on them, suggesting that these features are extremely young relative to the 4.5 billion year history of Mars. It is possible that these landforms are still being created by water seeping from the layered rock in the crater wall today. The crater has no name and it is located near 37.4°S, 168.0°W. The composite view in the lower left includes a picture taken by MOC on September 10, 1999, a picture obtained April 26, 2000, and another on May 22, 2000. The scene from left to right (including the dark gap between photos) covers an area approximately 7.6 kilometers (4.7 miles) wide by 18 km (11.1 mi) long. Sunlight illuminates the scene from the upper left. MOC high resolution images are taken black-and-white (grayscale), the color seen here has been synthesized from the colors of Mars observed by the MOC wide angle cameras and by the Viking Orbiters in the late 1970s. Photo Credit: NASA/JPL/Malin Space Science Systems

Cracks in Utopia

PIA01343

Sol (our sun)

Mars Orbiter Camera

Title	Cracks in Utopia
Original Caption Released with Image	Many of the craters found on the northern plains of Mars have been partly filled or buried by some material (possibly sediment). The Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) image presented here (MOC2-136b, above left) shows a high-resolution view of a tiny portion of the floor of one of these northern plains craters. The crater, located in Utopia Planitia at 44°N, 258°W, is shown on the right (MOC2-136a)with a small white box to indicate the location of the MOC image. The MOC image reveals that the material covering the floor of this crater is cracked and pitted. The origin and source of material that has been deposited in this crater is unknown. The MOC image was acquired in June 1999 and covers an area only 1.1 kilometers (0.7 miles) wide at a resolution of 1.8 meters (6 feet) per pixel. The context picture is a mosaic of Viking 2 orbiter images 010B53 and 010B55, taken in 1976. Both images are illuminated from the left. Malin Space Science Systems and the California Institute of Technology built the MOC using spare hardware from the Mars Observer mission. MSSS operates the camera from its facilities in San Diego, CA. The Jet Propulsion Laboratory's Mars Surveyor Operations Project operates the Mars Global Surveyor spacecraft with its industrial partner, Lockheed Martin Astronautics, from facilities in Pasadena, CA and Denver, CO.

Recently-Formed Impact Crate …

PIA04292

Sol (our sun)

Mars Orbiter Camera

Title	Recently-Formed Impact Crater
Original Caption Released with Image	Scientists using the Mars Orbiter Camera on NASA's Mars Global Surveyor spacecraft have discovered a crater that appears to have formed on Mars in the past 20 or so Earth years, and have used it and several other similar craters to estimate the present cratering rate on Mars. One of the basic tenets of planetary geology is that impact craters have accumulated on planetary surfaces at roughly a constant rate since the early history of the solar system. This appears to have been the case for small craters on the surface of the Moon, as shown by measurements of the length of time that lunar rocks created by small impacts have been exposed to cosmic rays, as determined by laboratory measurements of samples returned to Earth by the Apollo astronauts. This principle should permit the number of craters found on a planetary surface to be used to determine the age of that surface, if the rate at which new craters form is known. Scientists have previously estimated the cratering rate of Mars by scaling the lunar cratering rate based on the proximity of Mars to the asteroid belt, and by performing calculations based on orbital mechanics. Another way to establish the cratering rate of Mars would be to use long-term observations, say, from orbiting spacecraft, to actually locate new craters. The new crater is located on the southern rim of the summit crater, or caldera, of the intermediate-sized martian volcano, Ulysses Patera. The site was imaged by the Viking 2 orbiter in 1976 (left, an enlarged portion of the image) and in narrow-angle views by the Mars Orbiter Camera in 1999 (center) and 2005 (right). The new crater, about 25 meters (82 feet) across, is marked by a distinct dark, rayed pattern of ejected material, or ejecta, which is seen to have faded somewhat between 1999 and 2005. Ulysses Patera, a volcanic shield about 100 kilometers (62 miles) in diameter volcanic shield, located near 2.5 degrees north latitude, 121.3 degrees west longitude, is one of the Tharsis volcanoes and is partly buried by younger lava flows. The summit caldera is about 55 kilometers (34 miles) in diameter. The amount that the crater's rays faded between 1999 and 2005 can be used to help estimate how many years ago the crater formed. The actual contrast between the ejecta and the undisturbed volcano summit materials is actually much less than it appears to be in these processed images, and the amount of fading is also much less. Images of disturbed surfaces from various parts of Mars, such as dust devil tracks, dark slope streaks and rover tracks, indicate that disturbed surfaces on Mars are dark and that they lighten with time. Using these other examples to estimate how dark the ejecta from the Ulysses crater was originally, and how much it has faded in six years, suggests the crater formed in the early to mid 1980s. The rate at which dark surfaces lighten on Mars is not uniform over the whole planet, but scientists using the Mars Orbiter Camera have found a, number of other craters with dark ejecta that have faded during the Mars Global Surveyor mission. The scientists estimate that these craters probably formed within the past 100 years. Although the sample is very small (the Mars Orbiter Camera narrow angle camera has imaged barely 4 percent of Mars), it appears that the recent cratering rate for craters on Mars 25 to 100 meters (82 to 328 feet) in diameter is about 0.000000003 to 0.000000006 craters per square kilometer (0.39 square mile) per Earth year, which is about five times lower than previous estimates. The site of the new crater is shown in wider context in a comparison of the 1976 Viking image with wide-angle views taken by the Mars Orbiter Camera in 1999 and 2005 (figure 2), and in even wider context in a regional mosaic of Viking images (figure 3). The Mars Orbiter Camera was built and is operated by Malin Space Science Systems, San Diego, Calif. Mars Global Surveyor left Earth on Nov. 7, 1996, and began orbiting Mars on Sept. 12, 1997. JPL, a division of the California Institute of Technology, Pasadena, manages Mars Global Surveyor for NASA's Science Mission Directorate, Washington.

Recently-Formed Impact Crate …

PIA04292

Sol (our sun)

Mars Orbiter Camera

Title	Recently-Formed Impact Crater
Original Caption Released with Image	Scientists using the Mars Orbiter Camera on NASA's Mars Global Surveyor spacecraft have discovered a crater that appears to have formed on Mars in the past 20 or so Earth years, and have used it and several other similar craters to estimate the present cratering rate on Mars. One of the basic tenets of planetary geology is that impact craters have accumulated on planetary surfaces at roughly a constant rate since the early history of the solar system. This appears to have been the case for small craters on the surface of the Moon, as shown by measurements of the length of time that lunar rocks created by small impacts have been exposed to cosmic rays, as determined by laboratory measurements of samples returned to Earth by the Apollo astronauts. This principle should permit the number of craters found on a planetary surface to be used to determine the age of that surface, if the rate at which new craters form is known. Scientists have previously estimated the cratering rate of Mars by scaling the lunar cratering rate based on the proximity of Mars to the asteroid belt, and by performing calculations based on orbital mechanics. Another way to establish the cratering rate of Mars would be to use long-term observations, say, from orbiting spacecraft, to actually locate new craters. The new crater is located on the southern rim of the summit crater, or caldera, of the intermediate-sized martian volcano, Ulysses Patera. The site was imaged by the Viking 2 orbiter in 1976 (left, an enlarged portion of the image) and in narrow-angle views by the Mars Orbiter Camera in 1999 (center) and 2005 (right). The new crater, about 25 meters (82 feet) across, is marked by a distinct dark, rayed pattern of ejected material, or ejecta, which is seen to have faded somewhat between 1999 and 2005. Ulysses Patera, a volcanic shield about 100 kilometers (62 miles) in diameter volcanic shield, located near 2.5 degrees north latitude, 121.3 degrees west longitude, is one of the Tharsis volcanoes and is partly buried by younger lava flows. The summit caldera is about 55 kilometers (34 miles) in diameter. The amount that the crater's rays faded between 1999 and 2005 can be used to help estimate how many years ago the crater formed. The actual contrast between the ejecta and the undisturbed volcano summit materials is actually much less than it appears to be in these processed images, and the amount of fading is also much less. Images of disturbed surfaces from various parts of Mars, such as dust devil tracks, dark slope streaks and rover tracks, indicate that disturbed surfaces on Mars are dark and that they lighten with time. Using these other examples to estimate how dark the ejecta from the Ulysses crater was originally, and how much it has faded in six years, suggests the crater formed in the early to mid 1980s. The rate at which dark surfaces lighten on Mars is not uniform over the whole planet, but scientists using the Mars Orbiter Camera have found a, number of other craters with dark ejecta that have faded during the Mars Global Surveyor mission. The scientists estimate that these craters probably formed within the past 100 years. Although the sample is very small (the Mars Orbiter Camera narrow angle camera has imaged barely 4 percent of Mars), it appears that the recent cratering rate for craters on Mars 25 to 100 meters (82 to 328 feet) in diameter is about 0.000000003 to 0.000000006 craters per square kilometer (0.39 square mile) per Earth year, which is about five times lower than previous estimates. The site of the new crater is shown in wider context in a comparison of the 1976 Viking image with wide-angle views taken by the Mars Orbiter Camera in 1999 and 2005 (figure 2), and in even wider context in a regional mosaic of Viking images (figure 3). The Mars Orbiter Camera was built and is operated by Malin Space Science Systems, San Diego, Calif. Mars Global Surveyor left Earth on Nov. 7, 1996, and began orbiting Mars on Sept. 12, 1997. JPL, a division of the California Institute of Technology, Pasadena, manages Mars Global Surveyor for NASA's Science Mission Directorate, Washington.

Recently-Formed Impact Crate …

PIA04292

Sol (our sun)

Mars Orbiter Camera

Title	Recently-Formed Impact Crater
Original Caption Released with Image	Scientists using the Mars Orbiter Camera on NASA's Mars Global Surveyor spacecraft have discovered a crater that appears to have formed on Mars in the past 20 or so Earth years, and have used it and several other similar craters to estimate the present cratering rate on Mars. One of the basic tenets of planetary geology is that impact craters have accumulated on planetary surfaces at roughly a constant rate since the early history of the solar system. This appears to have been the case for small craters on the surface of the Moon, as shown by measurements of the length of time that lunar rocks created by small impacts have been exposed to cosmic rays, as determined by laboratory measurements of samples returned to Earth by the Apollo astronauts. This principle should permit the number of craters found on a planetary surface to be used to determine the age of that surface, if the rate at which new craters form is known. Scientists have previously estimated the cratering rate of Mars by scaling the lunar cratering rate based on the proximity of Mars to the asteroid belt, and by performing calculations based on orbital mechanics. Another way to establish the cratering rate of Mars would be to use long-term observations, say, from orbiting spacecraft, to actually locate new craters. The new crater is located on the southern rim of the summit crater, or caldera, of the intermediate-sized martian volcano, Ulysses Patera. The site was imaged by the Viking 2 orbiter in 1976 (left, an enlarged portion of the image) and in narrow-angle views by the Mars Orbiter Camera in 1999 (center) and 2005 (right). The new crater, about 25 meters (82 feet) across, is marked by a distinct dark, rayed pattern of ejected material, or ejecta, which is seen to have faded somewhat between 1999 and 2005. Ulysses Patera, a volcanic shield about 100 kilometers (62 miles) in diameter volcanic shield, located near 2.5 degrees north latitude, 121.3 degrees west longitude, is one of the Tharsis volcanoes and is partly buried by younger lava flows. The summit caldera is about 55 kilometers (34 miles) in diameter. The amount that the crater's rays faded between 1999 and 2005 can be used to help estimate how many years ago the crater formed. The actual contrast between the ejecta and the undisturbed volcano summit materials is actually much less than it appears to be in these processed images, and the amount of fading is also much less. Images of disturbed surfaces from various parts of Mars, such as dust devil tracks, dark slope streaks and rover tracks, indicate that disturbed surfaces on Mars are dark and that they lighten with time. Using these other examples to estimate how dark the ejecta from the Ulysses crater was originally, and how much it has faded in six years, suggests the crater formed in the early to mid 1980s. The rate at which dark surfaces lighten on Mars is not uniform over the whole planet, but scientists using the Mars Orbiter Camera have found a, number of other craters with dark ejecta that have faded during the Mars Global Surveyor mission. The scientists estimate that these craters probably formed within the past 100 years. Although the sample is very small (the Mars Orbiter Camera narrow angle camera has imaged barely 4 percent of Mars), it appears that the recent cratering rate for craters on Mars 25 to 100 meters (82 to 328 feet) in diameter is about 0.000000003 to 0.000000006 craters per square kilometer (0.39 square mile) per Earth year, which is about five times lower than previous estimates. The site of the new crater is shown in wider context in a comparison of the 1976 Viking image with wide-angle views taken by the Mars Orbiter Camera in 1999 and 2005 (figure 2), and in even wider context in a regional mosaic of Viking images (figure 3). The Mars Orbiter Camera was built and is operated by Malin Space Science Systems, San Diego, Calif. Mars Global Surveyor left Earth on Nov. 7, 1996, and began orbiting Mars on Sept. 12, 1997. JPL, a division of the California Institute of Technology, Pasadena, manages Mars Global Surveyor for NASA's Science Mission Directorate, Washington.

Recently-Formed Impact Crate …

PIA04292

Sol (our sun)

Mars Orbiter Camera

Title	Recently-Formed Impact Crater
Original Caption Released with Image	Scientists using the Mars Orbiter Camera on NASA's Mars Global Surveyor spacecraft have discovered a crater that appears to have formed on Mars in the past 20 or so Earth years, and have used it and several other similar craters to estimate the present cratering rate on Mars. One of the basic tenets of planetary geology is that impact craters have accumulated on planetary surfaces at roughly a constant rate since the early history of the solar system. This appears to have been the case for small craters on the surface of the Moon, as shown by measurements of the length of time that lunar rocks created by small impacts have been exposed to cosmic rays, as determined by laboratory measurements of samples returned to Earth by the Apollo astronauts. This principle should permit the number of craters found on a planetary surface to be used to determine the age of that surface, if the rate at which new craters form is known. Scientists have previously estimated the cratering rate of Mars by scaling the lunar cratering rate based on the proximity of Mars to the asteroid belt, and by performing calculations based on orbital mechanics. Another way to establish the cratering rate of Mars would be to use long-term observations, say, from orbiting spacecraft, to actually locate new craters. The new crater is located on the southern rim of the summit crater, or caldera, of the intermediate-sized martian volcano, Ulysses Patera. The site was imaged by the Viking 2 orbiter in 1976 (left, an enlarged portion of the image) and in narrow-angle views by the Mars Orbiter Camera in 1999 (center) and 2005 (right). The new crater, about 25 meters (82 feet) across, is marked by a distinct dark, rayed pattern of ejected material, or ejecta, which is seen to have faded somewhat between 1999 and 2005. Ulysses Patera, a volcanic shield about 100 kilometers (62 miles) in diameter volcanic shield, located near 2.5 degrees north latitude, 121.3 degrees west longitude, is one of the Tharsis volcanoes and is partly buried by younger lava flows. The summit caldera is about 55 kilometers (34 miles) in diameter. The amount that the crater's rays faded between 1999 and 2005 can be used to help estimate how many years ago the crater formed. The actual contrast between the ejecta and the undisturbed volcano summit materials is actually much less than it appears to be in these processed images, and the amount of fading is also much less. Images of disturbed surfaces from various parts of Mars, such as dust devil tracks, dark slope streaks and rover tracks, indicate that disturbed surfaces on Mars are dark and that they lighten with time. Using these other examples to estimate how dark the ejecta from the Ulysses crater was originally, and how much it has faded in six years, suggests the crater formed in the early to mid 1980s. The rate at which dark surfaces lighten on Mars is not uniform over the whole planet, but scientists using the Mars Orbiter Camera have found a, number of other craters with dark ejecta that have faded during the Mars Global Surveyor mission. The scientists estimate that these craters probably formed within the past 100 years. Although the sample is very small (the Mars Orbiter Camera narrow angle camera has imaged barely 4 percent of Mars), it appears that the recent cratering rate for craters on Mars 25 to 100 meters (82 to 328 feet) in diameter is about 0.000000003 to 0.000000006 craters per square kilometer (0.39 square mile) per Earth year, which is about five times lower than previous estimates. The site of the new crater is shown in wider context in a comparison of the 1976 Viking image with wide-angle views taken by the Mars Orbiter Camera in 1999 and 2005 (figure 2), and in even wider context in a regional mosaic of Viking images (figure 3). The Mars Orbiter Camera was built and is operated by Malin Space Science Systems, San Diego, Calif. Mars Global Surveyor left Earth on Nov. 7, 1996, and began orbiting Mars on Sept. 12, 1997. JPL, a division of the California Institute of Technology, Pasadena, manages Mars Global Surveyor for NASA's Science Mission Directorate, Washington.

Recently-Formed Impact Crate …

PIA04292

Sol (our sun)

Mars Orbiter Camera

Title	Recently-Formed Impact Crater
Original Caption Released with Image	Scientists using the Mars Orbiter Camera on NASA's Mars Global Surveyor spacecraft have discovered a crater that appears to have formed on Mars in the past 20 or so Earth years, and have used it and several other similar craters to estimate the present cratering rate on Mars. One of the basic tenets of planetary geology is that impact craters have accumulated on planetary surfaces at roughly a constant rate since the early history of the solar system. This appears to have been the case for small craters on the surface of the Moon, as shown by measurements of the length of time that lunar rocks created by small impacts have been exposed to cosmic rays, as determined by laboratory measurements of samples returned to Earth by the Apollo astronauts. This principle should permit the number of craters found on a planetary surface to be used to determine the age of that surface, if the rate at which new craters form is known. Scientists have previously estimated the cratering rate of Mars by scaling the lunar cratering rate based on the proximity of Mars to the asteroid belt, and by performing calculations based on orbital mechanics. Another way to establish the cratering rate of Mars would be to use long-term observations, say, from orbiting spacecraft, to actually locate new craters. The new crater is located on the southern rim of the summit crater, or caldera, of the intermediate-sized martian volcano, Ulysses Patera. The site was imaged by the Viking 2 orbiter in 1976 (left, an enlarged portion of the image) and in narrow-angle views by the Mars Orbiter Camera in 1999 (center) and 2005 (right). The new crater, about 25 meters (82 feet) across, is marked by a distinct dark, rayed pattern of ejected material, or ejecta, which is seen to have faded somewhat between 1999 and 2005. Ulysses Patera, a volcanic shield about 100 kilometers (62 miles) in diameter volcanic shield, located near 2.5 degrees north latitude, 121.3 degrees west longitude, is one of the Tharsis volcanoes and is partly buried by younger lava flows. The summit caldera is about 55 kilometers (34 miles) in diameter. The amount that the crater's rays faded between 1999 and 2005 can be used to help estimate how many years ago the crater formed. The actual contrast between the ejecta and the undisturbed volcano summit materials is actually much less than it appears to be in these processed images, and the amount of fading is also much less. Images of disturbed surfaces from various parts of Mars, such as dust devil tracks, dark slope streaks and rover tracks, indicate that disturbed surfaces on Mars are dark and that they lighten with time. Using these other examples to estimate how dark the ejecta from the Ulysses crater was originally, and how much it has faded in six years, suggests the crater formed in the early to mid 1980s. The rate at which dark surfaces lighten on Mars is not uniform over the whole planet, but scientists using the Mars Orbiter Camera have found a, number of other craters with dark ejecta that have faded during the Mars Global Surveyor mission. The scientists estimate that these craters probably formed within the past 100 years. Although the sample is very small (the Mars Orbiter Camera narrow angle camera has imaged barely 4 percent of Mars), it appears that the recent cratering rate for craters on Mars 25 to 100 meters (82 to 328 feet) in diameter is about 0.000000003 to 0.000000006 craters per square kilometer (0.39 square mile) per Earth year, which is about five times lower than previous estimates. The site of the new crater is shown in wider context in a comparison of the 1976 Viking image with wide-angle views taken by the Mars Orbiter Camera in 1999 and 2005 (figure 2), and in even wider context in a regional mosaic of Viking images (figure 3). The Mars Orbiter Camera was built and is operated by Malin Space Science Systems, San Diego, Calif. Mars Global Surveyor left Earth on Nov. 7, 1996, and began orbiting Mars on Sept. 12, 1997. JPL, a division of the California Institute of Technology, Pasadena, manages Mars Global Surveyor for NASA's Science Mission Directorate, Washington.

Recently-Formed Impact Crate …

PIA04292

Sol (our sun)

Mars Orbiter Camera

Title	Recently-Formed Impact Crater
Original Caption Released with Image	Scientists using the Mars Orbiter Camera on NASA's Mars Global Surveyor spacecraft have discovered a crater that appears to have formed on Mars in the past 20 or so Earth years, and have used it and several other similar craters to estimate the present cratering rate on Mars. One of the basic tenets of planetary geology is that impact craters have accumulated on planetary surfaces at roughly a constant rate since the early history of the solar system. This appears to have been the case for small craters on the surface of the Moon, as shown by measurements of the length of time that lunar rocks created by small impacts have been exposed to cosmic rays, as determined by laboratory measurements of samples returned to Earth by the Apollo astronauts. This principle should permit the number of craters found on a planetary surface to be used to determine the age of that surface, if the rate at which new craters form is known. Scientists have previously estimated the cratering rate of Mars by scaling the lunar cratering rate based on the proximity of Mars to the asteroid belt, and by performing calculations based on orbital mechanics. Another way to establish the cratering rate of Mars would be to use long-term observations, say, from orbiting spacecraft, to actually locate new craters. The new crater is located on the southern rim of the summit crater, or caldera, of the intermediate-sized martian volcano, Ulysses Patera. The site was imaged by the Viking 2 orbiter in 1976 (left, an enlarged portion of the image) and in narrow-angle views by the Mars Orbiter Camera in 1999 (center) and 2005 (right). The new crater, about 25 meters (82 feet) across, is marked by a distinct dark, rayed pattern of ejected material, or ejecta, which is seen to have faded somewhat between 1999 and 2005. Ulysses Patera, a volcanic shield about 100 kilometers (62 miles) in diameter volcanic shield, located near 2.5 degrees north latitude, 121.3 degrees west longitude, is one of the Tharsis volcanoes and is partly buried by younger lava flows. The summit caldera is about 55 kilometers (34 miles) in diameter. The amount that the crater's rays faded between 1999 and 2005 can be used to help estimate how many years ago the crater formed. The actual contrast between the ejecta and the undisturbed volcano summit materials is actually much less than it appears to be in these processed images, and the amount of fading is also much less. Images of disturbed surfaces from various parts of Mars, such as dust devil tracks, dark slope streaks and rover tracks, indicate that disturbed surfaces on Mars are dark and that they lighten with time. Using these other examples to estimate how dark the ejecta from the Ulysses crater was originally, and how much it has faded in six years, suggests the crater formed in the early to mid 1980s. The rate at which dark surfaces lighten on Mars is not uniform over the whole planet, but scientists using the Mars Orbiter Camera have found a, number of other craters with dark ejecta that have faded during the Mars Global Surveyor mission. The scientists estimate that these craters probably formed within the past 100 years. Although the sample is very small (the Mars Orbiter Camera narrow angle camera has imaged barely 4 percent of Mars), it appears that the recent cratering rate for craters on Mars 25 to 100 meters (82 to 328 feet) in diameter is about 0.000000003 to 0.000000006 craters per square kilometer (0.39 square mile) per Earth year, which is about five times lower than previous estimates. The site of the new crater is shown in wider context in a comparison of the 1976 Viking image with wide-angle views taken by the Mars Orbiter Camera in 1999 and 2005 (figure 2), and in even wider context in a regional mosaic of Viking images (figure 3). The Mars Orbiter Camera was built and is operated by Malin Space Science Systems, San Diego, Calif. Mars Global Surveyor left Earth on Nov. 7, 1996, and began orbiting Mars on Sept. 12, 1997. JPL, a division of the California Institute of Technology, Pasadena, manages Mars Global Surveyor for NASA's Science Mission Directorate, Washington.

Evidence for Recent Liquid Water on Mars: Gullies at 70°S in Polar Pit Walls

Evidence for Recent Liquid W …

PIA01034

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Gullies at 70°S in Polar Pit Walls
Original Caption Released with Image	Gully landforms proposed to have been caused by geologically-recent seepage and runoff of liquid water on Mars are found in the most unlikely places. They typically occur in areas that are quite cold--well below freezing--all year round. Like the old adage about moss on trees, nearly all of them form on slopes that face away from sunlight. Most of the gullies occur at latitudes between 30° and 70°. The highest latitude at which martian gullies have been found is around 70°-75°S on the walls of pits developed in the south polar pitted plains. If you were at this same latitude on Earth, you would be in Antarctica. This region spends much of the winter--which lasts approximately 6 months on Mars--in darkness and at temperatures cold enough to freeze carbon dioxide (around -130°C or -200°F). Nevertheless, gullies with very sharp, deep, v-shaped channels are seen on the pit walls (above, left). Based upon the locations of the tops of the channels on the slope shown here, the inferred site of liquid seepage is located at a layer in the pit wall about 1/3 of the way down from the top of the MOC image. The channels start wide and taper downslope. The area above the channels is layered and has been eroded by mass movement--dry avalanching of debris--to form a pattern of chutes and ridges on the upper slope of the pit wall. The top layer appears to have many boulders in it (each about the size of a small house), these boulders are left behind on the upper slopes of the pit wall as debris is removed. Centered near 70.7°S, 355.7°W, the MOC image was acquired July 14, 1999, and covers an area approximately 2.8 km (1.7 mi) wide by 2.1 km(1.3 mi) high. Sunlight illuminates the MOC image from the upper left and north is toward the upper left. The context view (right) is from the Viking 2 orbiter and was acquired in 1977. The Viking picture is illuminated from the top/upper left, north is toward the upper right. The small white box in the context frame (upper right corner) shows the location of the high resolution MOC view.

Evidence for Recent Liquid W …

PIA01034

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Gullies at 70°S in Polar Pit Walls
Original Caption Released with Image	Gully landforms proposed to have been caused by geologically-recent seepage and runoff of liquid water on Mars are found in the most unlikely places. They typically occur in areas that are quite cold--well below freezing--all year round. Like the old adage about moss on trees, nearly all of them form on slopes that face away from sunlight. Most of the gullies occur at latitudes between 30° and 70°. The highest latitude at which martian gullies have been found is around 70°-75°S on the walls of pits developed in the south polar pitted plains. If you were at this same latitude on Earth, you would be in Antarctica. This region spends much of the winter--which lasts approximately 6 months on Mars--in darkness and at temperatures cold enough to freeze carbon dioxide (around -130°C or -200°F). Nevertheless, gullies with very sharp, deep, v-shaped channels are seen on the pit walls (above, left). Based upon the locations of the tops of the channels on the slope shown here, the inferred site of liquid seepage is located at a layer in the pit wall about 1/3 of the way down from the top of the MOC image. The channels start wide and taper downslope. The area above the channels is layered and has been eroded by mass movement--dry avalanching of debris--to form a pattern of chutes and ridges on the upper slope of the pit wall. The top layer appears to have many boulders in it (each about the size of a small house), these boulders are left behind on the upper slopes of the pit wall as debris is removed. Centered near 70.7°S, 355.7°W, the MOC image was acquired July 14, 1999, and covers an area approximately 2.8 km (1.7 mi) wide by 2.1 km(1.3 mi) high. Sunlight illuminates the MOC image from the upper left and north is toward the upper left. The context view (right) is from the Viking 2 orbiter and was acquired in 1977. The Viking picture is illuminated from the top/upper left, north is toward the upper right. The small white box in the context frame (upper right corner) shows the location of the high resolution MOC view.

Evidence for Recent Liquid W …

PIA01034

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Gullies at 70°S in Polar Pit Walls
Original Caption Released with Image	Gully landforms proposed to have been caused by geologically-recent seepage and runoff of liquid water on Mars are found in the most unlikely places. They typically occur in areas that are quite cold--well below freezing--all year round. Like the old adage about moss on trees, nearly all of them form on slopes that face away from sunlight. Most of the gullies occur at latitudes between 30° and 70°. The highest latitude at which martian gullies have been found is around 70°-75°S on the walls of pits developed in the south polar pitted plains. If you were at this same latitude on Earth, you would be in Antarctica. This region spends much of the winter--which lasts approximately 6 months on Mars--in darkness and at temperatures cold enough to freeze carbon dioxide (around -130°C or -200°F). Nevertheless, gullies with very sharp, deep, v-shaped channels are seen on the pit walls (above, left). Based upon the locations of the tops of the channels on the slope shown here, the inferred site of liquid seepage is located at a layer in the pit wall about 1/3 of the way down from the top of the MOC image. The channels start wide and taper downslope. The area above the channels is layered and has been eroded by mass movement--dry avalanching of debris--to form a pattern of chutes and ridges on the upper slope of the pit wall. The top layer appears to have many boulders in it (each about the size of a small house), these boulders are left behind on the upper slopes of the pit wall as debris is removed. Centered near 70.7°S, 355.7°W, the MOC image was acquired July 14, 1999, and covers an area approximately 2.8 km (1.7 mi) wide by 2.1 km(1.3 mi) high. Sunlight illuminates the MOC image from the upper left and north is toward the upper left. The context view (right) is from the Viking 2 orbiter and was acquired in 1977. The Viking picture is illuminated from the top/upper left, north is toward the upper right. The small white box in the context frame (upper right corner) shows the location of the high resolution MOC view.

Evidence for Recent Liquid Water on Mars: Seepage Sites in "Aerobraking Crater" Revisited

Evidence for Recent Liquid W …

PIA01036

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Seepage Sites in "Aerobraking Crater" Revisited
Original Caption Released with Image	The first clue that there might be places on Mars where liquid groundwater seeps out onto the surface came from a picture taken by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) during the pre-mapping Orbit Insertion Phase of the mission. The picture, shown in (A)above, was taken at the end of December 1997 while the spacecraft was still in the midst of aerobraking maneuvers to put it into the circular orbit needed for the Mapping Phase of the project. The Aerobraking 1 image, AB1-07707, showed dark, v-shaped scars on the western wall of a 50 kilometer-(31 mile)-diameter impact crater in southern Noachis Terra at 65°S, 15°W (see B, above, for context). The v-shaped features taper downslope to form narrow, somewhat curved channels. The relationship seen here was interpreted by MOC scientists to be similar to seepage landforms on Earth that form where springs emerge on a slope and water runs downhill. Once MGS achieved its Mapping Orbit in March 1999, the MOC was in a better position to take pictures of 10 times higher resolution than the Aerobraking AB1-07707 image. The opportunity to take a new picture of the proposed "seepage" sites on the wall of the crater in southern Noachis finally arose in January 2000. The result is MOC image M11-00530, shown above in (top) and (C). This new close-up shows that the darkly-shaped scars host many small channels of only a few meters (yards) across. These small channels run downslope and coalesce at the apex (or point) of each "v". Amid the small channels are many large boulders, some of them the size of houses, that have eroded out of the crater wall. A 3-D view created using the AB1 and M11 images is shown in (D). The stereo picture (red-blue "3D" glasses required) emphasizes the presence of small channels and valleys, and shows that these valleys start almost at the very top of the v-shaped dark areas. The context picture in (B) is a mosaic of Viking 2 orbiter images 497B47 and 497B48 acquired December 28, 1977. The Aerobraking MGS MOC image, AB1-07707, is shown overlain on the Viking context image, it was taken 20 years later on December 29, 1997. The smaller white box in the context picture shows the location of MOC Mapping Phase image M11-00530, roughly 2 years later on January 4, 2000. North is "up" in pictures (A) and (B), and to the lower right in (top), (C), and (D). Sunlight illuminates (A) from the upper left, (B) from the upper right, and (top) and (C) from the upper right. The top image in (top) is the aerobraking image, AB1-07707, with a white box indicating the location of the lower image, M11-00530, and the stereo pair in (D). The white box on the left in (C) shows the location of the close-up on the right in (C).

Evidence for Recent Liquid W …

PIA01036

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Seepage Sites in "Aerobraking Crater" Revisited
Original Caption Released with Image	The first clue that there might be places on Mars where liquid groundwater seeps out onto the surface came from a picture taken by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) during the pre-mapping Orbit Insertion Phase of the mission. The picture, shown in (A)above, was taken at the end of December 1997 while the spacecraft was still in the midst of aerobraking maneuvers to put it into the circular orbit needed for the Mapping Phase of the project. The Aerobraking 1 image, AB1-07707, showed dark, v-shaped scars on the western wall of a 50 kilometer-(31 mile)-diameter impact crater in southern Noachis Terra at 65°S, 15°W (see B, above, for context). The v-shaped features taper downslope to form narrow, somewhat curved channels. The relationship seen here was interpreted by MOC scientists to be similar to seepage landforms on Earth that form where springs emerge on a slope and water runs downhill. Once MGS achieved its Mapping Orbit in March 1999, the MOC was in a better position to take pictures of 10 times higher resolution than the Aerobraking AB1-07707 image. The opportunity to take a new picture of the proposed "seepage" sites on the wall of the crater in southern Noachis finally arose in January 2000. The result is MOC image M11-00530, shown above in (top) and (C). This new close-up shows that the darkly-shaped scars host many small channels of only a few meters (yards) across. These small channels run downslope and coalesce at the apex (or point) of each "v". Amid the small channels are many large boulders, some of them the size of houses, that have eroded out of the crater wall. A 3-D view created using the AB1 and M11 images is shown in (D). The stereo picture (red-blue "3D" glasses required) emphasizes the presence of small channels and valleys, and shows that these valleys start almost at the very top of the v-shaped dark areas. The context picture in (B) is a mosaic of Viking 2 orbiter images 497B47 and 497B48 acquired December 28, 1977. The Aerobraking MGS MOC image, AB1-07707, is shown overlain on the Viking context image, it was taken 20 years later on December 29, 1997. The smaller white box in the context picture shows the location of MOC Mapping Phase image M11-00530, roughly 2 years later on January 4, 2000. North is "up" in pictures (A) and (B), and to the lower right in (top), (C), and (D). Sunlight illuminates (A) from the upper left, (B) from the upper right, and (top) and (C) from the upper right. The top image in (top) is the aerobraking image, AB1-07707, with a white box indicating the location of the lower image, M11-00530, and the stereo pair in (D). The white box on the left in (C) shows the location of the close-up on the right in (C).

Evidence for Recent Liquid W …

PIA01036

Sol (our sun)

Mars Orbiter Camera

Title	Evidence for Recent Liquid Water on Mars: Seepage Sites in "Aerobraking Crater" Revisited
Original Caption Released with Image	The first clue that there might be places on Mars where liquid groundwater seeps out onto the surface came from a picture taken by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) during the pre-mapping Orbit Insertion Phase of the mission. The picture, shown in (A)above, was taken at the end of December 1997 while the spacecraft was still in the midst of aerobraking maneuvers to put it into the circular orbit needed for the Mapping Phase of the project. The Aerobraking 1 image, AB1-07707, showed dark, v-shaped scars on the western wall of a 50 kilometer-(31 mile)-diameter impact crater in southern Noachis Terra at 65°S, 15°W (see B, above, for context). The v-shaped features taper downslope to form narrow, somewhat curved channels. The relationship seen here was interpreted by MOC scientists to be similar to seepage landforms on Earth that form where springs emerge on a slope and water runs downhill. Once MGS achieved its Mapping Orbit in March 1999, the MOC was in a better position to take pictures of 10 times higher resolution than the Aerobraking AB1-07707 image. The opportunity to take a new picture of the proposed "seepage" sites on the wall of the crater in southern Noachis finally arose in January 2000. The result is MOC image M11-00530, shown above in (top) and (C). This new close-up shows that the darkly-shaped scars host many small channels of only a few meters (yards) across. These small channels run downslope and coalesce at the apex (or point) of each "v". Amid the small channels are many large boulders, some of them the size of houses, that have eroded out of the crater wall. A 3-D view created using the AB1 and M11 images is shown in (D). The stereo picture (red-blue "3D" glasses required) emphasizes the presence of small channels and valleys, and shows that these valleys start almost at the very top of the v-shaped dark areas. The context picture in (B) is a mosaic of Viking 2 orbiter images 497B47 and 497B48 acquired December 28, 1977. The Aerobraking MGS MOC image, AB1-07707, is shown overlain on the Viking context image, it was taken 20 years later on December 29, 1997. The smaller white box in the context picture shows the location of MOC Mapping Phase image M11-00530, roughly 2 years later on January 4, 2000. North is "up" in pictures (A) and (B), and to the lower right in (top), (C), and (D). Sunlight illuminates (A) from the upper left, (B) from the upper right, and (top) and (C) from the upper right. The top image in (top) is the aerobraking image, AB1-07707, with a white box indicating the location of the lower image, M11-00530, and the stereo pair in (D). The white box on the left in (C) shows the location of the close-up on the right in (C).

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