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Search Results: All Fields similar to 'Viking' and When equal to '2000'
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Evidence for Recent Liquid W
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| 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 |
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Crater Wall In Noachis Mars
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Signs of water erosion and d
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6/29/00
| Date |
6/29/00 |
| Description |
Signs of water erosion and debris flow are seen in this high resolution view of gullies eroded into the wall of a meteor impact crater in Noachis Terra on Mars, taken by NASA's Mars Global Surveyor. The image shows channels and associated aprons of debris, 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 the below the surface of Mars today. This picture was acquired by Mars Global Surveyor on September 28, 1999. The scene covers an area approximately 3 kilometers (about 2 miles) wide by 6.7 kilometers (4.1 miles) high. Sunlight illuminates this area from the upper left. The area covered in the image is located near 54.8 degrees South by 342.5 degrees West. The Mars Orbiter camera high-resolution images are taken in black-and-white (grayscale), the color seen here has been synthesized from the colors of Mars observed by the spacecraft's wide-angle cameras and by NASA's Viking Orbiters in the late 1970s. The Mars Global Surveyor mission is managed for NASA's Office of Space Science by the Jet Propulsion Laboratory, Pasadena, Calif. JPL is a division of the California Institute of Technology. ##### Images Credit: NASA/JPL/Malin Space Science Systems |
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89-HC-271
A paper collage interpreting
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4/26/00
| Description |
A paper collage interpreting the craters and ridged planes of Mars and the Viking 2 as it passed over Mar's surface on 2 November 1982, prior to landing. |
| Date |
4/26/00 |
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Evidence for Recent Liquid W
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| Title |
Evidence for Recent Liquid Water on Mars |
| Full Description |
This image, acquired by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) in May 2000 shows numerous examples of martian gullies that all start--or head--in a specific layer roughly a hundred meters beneath the surface of Mars. These features are located on the south-facing wall of a trough in the Gorgonum Chaos region, an area found to have many examples of gullies proposed to have formed by seepage and runoff of liquid water in recent martian times. The layer from which the gullies emanate has recessed backward to form an overhang beneath a harder layer of rock. The larger gullies have formed an alcove--an area above the overhang from which debris has collapsed to leave a dark-toned scar. Below the layer of seepage is found a dark, narrow channel that runs down the slope to an apron of debris. The small, bright, parallel features at the base of the cliff at the center-right of the picture is a series of large windblown ripples. Although the dark tone of the alcoves and channels in this image is not likely to be the result of wet ground (the contrast in this image has been enhanced), it does suggest that water has seeped out of the ground and moved down the slope quite recently. Sharp contrasts between dark and light areas are hard to maintain on Mars for very long periods of time because dust tends to coat surfaces and reduce brightness differences. To keep dust from settling on a surface, it has to have undergone some process of erosion (wind, landslides, water runoff) relatively recently. There is no way to know how recent this activity was, but educated guesses center between a few to tens of years, and it is entirely possible that the area shown in this image has water seeping out of the ground today. Centered near 37.9S, 170.2W, sunlight illuminates the MOC image from the upper left, north is toward the upper right. The context view above is from the Viking 1 orbiter and was acquired in 1977. The Viking picture is illuminated from the upper right, north is up. The small white box in the context frame shows the location of the high resolution MOC view. |
| Date |
06/22/2000 |
| NASA Center |
Jet Propulsion Laboratory |
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Gorgonum Crater Mars Global
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Numerous deep channels desce
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6/29/00
| Date |
6/29/00 |
| Description |
Numerous deep channels descending a Martian crater wall, and the debris they left behind, are seen in this mosaic of two images taken by the camera on NASA's Mars Global Surveyor. The area shown is the northwestern wall of an approximately 12 kilometer- (7.4 mile-) wide meteor crater east of the Gorgonum Chaos region in the Martian southern hemisphere. These are deep channels and the number of them and the debris they left behind indicate that as many as tens to hundreds of individual events involving the flow of water and debris have occurred here. The channels and the debris areas look sharp 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. This is a mosaic of pictures taken by Mars Global Surveyor on April 26, 2000, and May 22, 2000. The scene covers an area approximately 4 kilometers (2.5 miles) wide by 7.2 kilometers (4.5 miles) long. Sunlight illuminates the scene from the upper left. The image is located near 37.4 degrees South by 168.0 degrees West. The Mars Orbiter camera high-resolution images are taken in black-and- white (grayscale), the color seen here has been synthesized from the colors of Mars observed by the spacecraft's wide-angle cameras and by the Viking Orbiters in the late 1970s. The Mars Global Surveyor mission is managed for NASA's Office of Space Science by the Jet Propulsion Laboratory, Pasadena, Calif. JPL is a division of the California Institute of Technology. ##### Images Credit: NASA/JPL/Malin Space Science Systems |
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Layered Rock in Candor Chasm
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This high-resolution picture
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12/4/00
| Date |
12/4/00 |
| Description |
This high-resolution picture from NASA's Mars Global Surveyor was the first received by imaging scientists that began to hint at a larger story of layered sedimentary rock on Mars. These patterns could very well indicate that the materials were deposited in a lake or shallow sea. The picture shows a 1.5 kilometer-by-2.9 kilometer area (.9 mile- by-1.8 mile) in far southwestern Candor Chasma. Based on Mariner 9 and Viking orbiter images, this region was not known to exhibit layers. What is most striking about the picture is the large number and uniformity of the previously unexpected layers, or beds. There are more than 100 beds in this area, and each has about the same thickness (estimated to be about 10 meters, or 11 yards, thick). Each layer has a relatively smooth upper surface and each is hard enough to form steep cliffs at its margins. Layers indicate change. The uniform pattern seen here, with beds of similar properties and thickness repeated more than one hundred times, suggests that the deposition processes that made the layers were interrupted at regular or episodic intervals. Patterns like this, when found on Earth, usually indicate the presence of sediment deposited in dynamic, energetic, underwater environments. However, because these rocks are found on Mars, it is not known for certain that they formed underwater or whether there were once dry, atmospheric depositional processes operating on the planet that could create sedimentary rocks that mimic those formed in water. Mars Global Surveyor is managed for NASA's Office of Space Science, Washington, D.C., by the Jet Propulsion Laboratory, Pasadena, Calif. JPL is a division of the California Institute of Technology. Malin Space Science Systems, San Diego, Calif., built and operates the camera system. JPL's industrial partner is Lockheed Martin Astronautics, Denver, Colo., which developed and operates the spacecraft. ##### |
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Evidence for Recent Liquid W
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PIA01033
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Gullies in Gorgonum Chaos |
| Original Caption Released with Image |
The first two pictures (top and above left) are from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) and show a series of troughs and layered mesas in the Gorgonum Chaos region of the martian southern hemisphere. The picture at the top of the page is a portion of the picture on the left above. The Viking view (above right) shows the location of the MOC image in the chaotic terrain. Gullies proposed to have been formed by seeping groundwater emanate from a specific layer near the tops of trough walls, particularly on south-facing slopes (south is toward the bottom of each picture). The presence of so many gullies associated with the same layer in each mesa suggests that this layer is particularly effective in storing and conducting water. Such a layer is called an aquifer, and this one appears to be present less than a few hundred meters (few hundred yards) beneath the surface in this region. The MOC pictures were taken on January 22, 2000. The sample at the top of the page is an area 3 kilometers (1.9 miles) wide by 2.6 km (1.6 mi) high. The long view (above left) covers an area 3 kilometers (1.9 miles) wide by 22.6 km (14 mi) long. Sunlight illuminates each scene from the upper left. The images are located near 37.5°S, 170.5°W. The context image (above right) was acquired by the Viking 1 orbiter in 1977 and is illuminated from the upper right, north is up. 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. NOTE: A Full Resolution Grayscale view of the release image can be found here. |
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Evidence for Recent Liquid W
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PIA01033
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Gullies in Gorgonum Chaos |
| Original Caption Released with Image |
The first two pictures (top and above left) are from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) and show a series of troughs and layered mesas in the Gorgonum Chaos region of the martian southern hemisphere. The picture at the top of the page is a portion of the picture on the left above. The Viking view (above right) shows the location of the MOC image in the chaotic terrain. Gullies proposed to have been formed by seeping groundwater emanate from a specific layer near the tops of trough walls, particularly on south-facing slopes (south is toward the bottom of each picture). The presence of so many gullies associated with the same layer in each mesa suggests that this layer is particularly effective in storing and conducting water. Such a layer is called an aquifer, and this one appears to be present less than a few hundred meters (few hundred yards) beneath the surface in this region. The MOC pictures were taken on January 22, 2000. The sample at the top of the page is an area 3 kilometers (1.9 miles) wide by 2.6 km (1.6 mi) high. The long view (above left) covers an area 3 kilometers (1.9 miles) wide by 22.6 km (14 mi) long. Sunlight illuminates each scene from the upper left. The images are located near 37.5°S, 170.5°W. The context image (above right) was acquired by the Viking 1 orbiter in 1977 and is illuminated from the upper right, north is up. 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. NOTE: A Full Resolution Grayscale view of the release image can be found here. |
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Evidence for Recent Liquid W
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PIA01033
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Gullies in Gorgonum Chaos |
| Original Caption Released with Image |
The first two pictures (top and above left) are from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) and show a series of troughs and layered mesas in the Gorgonum Chaos region of the martian southern hemisphere. The picture at the top of the page is a portion of the picture on the left above. The Viking view (above right) shows the location of the MOC image in the chaotic terrain. Gullies proposed to have been formed by seeping groundwater emanate from a specific layer near the tops of trough walls, particularly on south-facing slopes (south is toward the bottom of each picture). The presence of so many gullies associated with the same layer in each mesa suggests that this layer is particularly effective in storing and conducting water. Such a layer is called an aquifer, and this one appears to be present less than a few hundred meters (few hundred yards) beneath the surface in this region. The MOC pictures were taken on January 22, 2000. The sample at the top of the page is an area 3 kilometers (1.9 miles) wide by 2.6 km (1.6 mi) high. The long view (above left) covers an area 3 kilometers (1.9 miles) wide by 22.6 km (14 mi) long. Sunlight illuminates each scene from the upper left. The images are located near 37.5°S, 170.5°W. The context image (above right) was acquired by the Viking 1 orbiter in 1977 and is illuminated from the upper right, north is up. 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. NOTE: A Full Resolution Grayscale view of the release image can be found here. |
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Evidence for Recent Liquid W
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PIA01033
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Gullies in Gorgonum Chaos |
| Original Caption Released with Image |
The first two pictures (top and above left) are from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) and show a series of troughs and layered mesas in the Gorgonum Chaos region of the martian southern hemisphere. The picture at the top of the page is a portion of the picture on the left above. The Viking view (above right) shows the location of the MOC image in the chaotic terrain. Gullies proposed to have been formed by seeping groundwater emanate from a specific layer near the tops of trough walls, particularly on south-facing slopes (south is toward the bottom of each picture). The presence of so many gullies associated with the same layer in each mesa suggests that this layer is particularly effective in storing and conducting water. Such a layer is called an aquifer, and this one appears to be present less than a few hundred meters (few hundred yards) beneath the surface in this region. The MOC pictures were taken on January 22, 2000. The sample at the top of the page is an area 3 kilometers (1.9 miles) wide by 2.6 km (1.6 mi) high. The long view (above left) covers an area 3 kilometers (1.9 miles) wide by 22.6 km (14 mi) long. Sunlight illuminates each scene from the upper left. The images are located near 37.5°S, 170.5°W. The context image (above right) was acquired by the Viking 1 orbiter in 1977 and is illuminated from the upper right, north is up. 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. NOTE: A Full Resolution Grayscale view of the release image can be found here. |
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Evidence for Recent Liquid W
…
PIA01033
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Gullies in Gorgonum Chaos |
| Original Caption Released with Image |
The first two pictures (top and above left) are from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) and show a series of troughs and layered mesas in the Gorgonum Chaos region of the martian southern hemisphere. The picture at the top of the page is a portion of the picture on the left above. The Viking view (above right) shows the location of the MOC image in the chaotic terrain. Gullies proposed to have been formed by seeping groundwater emanate from a specific layer near the tops of trough walls, particularly on south-facing slopes (south is toward the bottom of each picture). The presence of so many gullies associated with the same layer in each mesa suggests that this layer is particularly effective in storing and conducting water. Such a layer is called an aquifer, and this one appears to be present less than a few hundred meters (few hundred yards) beneath the surface in this region. The MOC pictures were taken on January 22, 2000. The sample at the top of the page is an area 3 kilometers (1.9 miles) wide by 2.6 km (1.6 mi) high. The long view (above left) covers an area 3 kilometers (1.9 miles) wide by 22.6 km (14 mi) long. Sunlight illuminates each scene from the upper left. The images are located near 37.5°S, 170.5°W. The context image (above right) was acquired by the Viking 1 orbiter in 1977 and is illuminated from the upper right, north is up. 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. NOTE: A Full Resolution Grayscale view of the release image can be found here. |
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Evidence for Recent Liquid W
…
PIA01033
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Gullies in Gorgonum Chaos |
| Original Caption Released with Image |
The first two pictures (top and above left) are from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) and show a series of troughs and layered mesas in the Gorgonum Chaos region of the martian southern hemisphere. The picture at the top of the page is a portion of the picture on the left above. The Viking view (above right) shows the location of the MOC image in the chaotic terrain. Gullies proposed to have been formed by seeping groundwater emanate from a specific layer near the tops of trough walls, particularly on south-facing slopes (south is toward the bottom of each picture). The presence of so many gullies associated with the same layer in each mesa suggests that this layer is particularly effective in storing and conducting water. Such a layer is called an aquifer, and this one appears to be present less than a few hundred meters (few hundred yards) beneath the surface in this region. The MOC pictures were taken on January 22, 2000. The sample at the top of the page is an area 3 kilometers (1.9 miles) wide by 2.6 km (1.6 mi) high. The long view (above left) covers an area 3 kilometers (1.9 miles) wide by 22.6 km (14 mi) long. Sunlight illuminates each scene from the upper left. The images are located near 37.5°S, 170.5°W. The context image (above right) was acquired by the Viking 1 orbiter in 1977 and is illuminated from the upper right, north is up. 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. NOTE: A Full Resolution Grayscale view of the release image can be found here. |
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Evidence for Recent Liquid W
…
PIA01033
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Gullies in Gorgonum Chaos |
| Original Caption Released with Image |
The first two pictures (top and above left) are from the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) and show a series of troughs and layered mesas in the Gorgonum Chaos region of the martian southern hemisphere. The picture at the top of the page is a portion of the picture on the left above. The Viking view (above right) shows the location of the MOC image in the chaotic terrain. Gullies proposed to have been formed by seeping groundwater emanate from a specific layer near the tops of trough walls, particularly on south-facing slopes (south is toward the bottom of each picture). The presence of so many gullies associated with the same layer in each mesa suggests that this layer is particularly effective in storing and conducting water. Such a layer is called an aquifer, and this one appears to be present less than a few hundred meters (few hundred yards) beneath the surface in this region. The MOC pictures were taken on January 22, 2000. The sample at the top of the page is an area 3 kilometers (1.9 miles) wide by 2.6 km (1.6 mi) high. The long view (above left) covers an area 3 kilometers (1.9 miles) wide by 22.6 km (14 mi) long. Sunlight illuminates each scene from the upper left. The images are located near 37.5°S, 170.5°W. The context image (above right) was acquired by the Viking 1 orbiter in 1977 and is illuminated from the upper right, north is up. 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. NOTE: A Full Resolution Grayscale view of the release image can be found here. |
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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 |
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Evidence for Recent Liquid W
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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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Evidence for Recent Liquid W
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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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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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Evidence for Recent Liquid W
…
PIA01032
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars:"Weeping" Layer in Gorgonum Chaos |
| Original Caption Released with Image |
This image, acquired by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) in May 2000 shows numerous examples of martian gullies that all start--or head--in a specific layer roughly a hundred meters beneath the surface of Mars. These features are located on the south-facing wall of a trough in the Gorgonum Chaos region, an area found to have many examples of gullies proposed to have formed by seepage and runoff of liquid water in recent martian times. The layer from which the gullies emanate has recessed backward to form an overhang beneath a harder layer of rock. The larger gullies have formed an alcove--an area above the overhang from which debris has collapsed to leave a dark-toned scar. Below the layer of seepage is found a dark, narrow channel that runs down the slope to an apron of debris. The small, bright, parallel features at the base of the cliff at the center-right of the picture is a series of large windblown ripples. Although the dark tone of the alcoves and channels in this image is not likely to be the result of wet ground (the contrast in this image has been enhanced), it does suggest that water has seeped out of the ground and moved down the slope quite recently. Sharp contrasts between dark and light areas are hard to maintain on Mars for very long periods of time because dust tends to coat surfaces and reduce brightness differences. To keep dust from settling on a surface, it has to have undergone some process of erosion (wind, landslides, water runoff) relatively recently. There is no way to know how recent this activity was, but educated guesses center between a few to tens of years, and it is entirely possible that the area shown in this image has water seeping out of the ground today. Centered near 37.9°S, 170.2°W, sunlight illuminates the MOC image from the upper left, north is toward the upper right. The context view above is from the Viking 1 orbiter and was acquired in 1977. The Viking picture is illuminated from the upper right, north is up. The small white box in the context frame shows the location of the high resolution MOC view. |
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Evidence for Recent Liquid W
…
PIA01032
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars:"Weeping" Layer in Gorgonum Chaos |
| Original Caption Released with Image |
This image, acquired by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) in May 2000 shows numerous examples of martian gullies that all start--or head--in a specific layer roughly a hundred meters beneath the surface of Mars. These features are located on the south-facing wall of a trough in the Gorgonum Chaos region, an area found to have many examples of gullies proposed to have formed by seepage and runoff of liquid water in recent martian times. The layer from which the gullies emanate has recessed backward to form an overhang beneath a harder layer of rock. The larger gullies have formed an alcove--an area above the overhang from which debris has collapsed to leave a dark-toned scar. Below the layer of seepage is found a dark, narrow channel that runs down the slope to an apron of debris. The small, bright, parallel features at the base of the cliff at the center-right of the picture is a series of large windblown ripples. Although the dark tone of the alcoves and channels in this image is not likely to be the result of wet ground (the contrast in this image has been enhanced), it does suggest that water has seeped out of the ground and moved down the slope quite recently. Sharp contrasts between dark and light areas are hard to maintain on Mars for very long periods of time because dust tends to coat surfaces and reduce brightness differences. To keep dust from settling on a surface, it has to have undergone some process of erosion (wind, landslides, water runoff) relatively recently. There is no way to know how recent this activity was, but educated guesses center between a few to tens of years, and it is entirely possible that the area shown in this image has water seeping out of the ground today. Centered near 37.9°S, 170.2°W, sunlight illuminates the MOC image from the upper left, north is toward the upper right. The context view above is from the Viking 1 orbiter and was acquired in 1977. The Viking picture is illuminated from the upper right, north is up. The small white box in the context frame shows the location of the high resolution MOC view. |
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Evidence for Recent Liquid W
…
PIA01032
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars:"Weeping" Layer in Gorgonum Chaos |
| Original Caption Released with Image |
This image, acquired by the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) in May 2000 shows numerous examples of martian gullies that all start--or head--in a specific layer roughly a hundred meters beneath the surface of Mars. These features are located on the south-facing wall of a trough in the Gorgonum Chaos region, an area found to have many examples of gullies proposed to have formed by seepage and runoff of liquid water in recent martian times. The layer from which the gullies emanate has recessed backward to form an overhang beneath a harder layer of rock. The larger gullies have formed an alcove--an area above the overhang from which debris has collapsed to leave a dark-toned scar. Below the layer of seepage is found a dark, narrow channel that runs down the slope to an apron of debris. The small, bright, parallel features at the base of the cliff at the center-right of the picture is a series of large windblown ripples. Although the dark tone of the alcoves and channels in this image is not likely to be the result of wet ground (the contrast in this image has been enhanced), it does suggest that water has seeped out of the ground and moved down the slope quite recently. Sharp contrasts between dark and light areas are hard to maintain on Mars for very long periods of time because dust tends to coat surfaces and reduce brightness differences. To keep dust from settling on a surface, it has to have undergone some process of erosion (wind, landslides, water runoff) relatively recently. There is no way to know how recent this activity was, but educated guesses center between a few to tens of years, and it is entirely possible that the area shown in this image has water seeping out of the ground today. Centered near 37.9°S, 170.2°W, sunlight illuminates the MOC image from the upper left, north is toward the upper right. The context view above is from the Viking 1 orbiter and was acquired in 1977. The Viking picture is illuminated from the upper right, north is up. The small white box in the context frame shows the location of the high resolution MOC view. |
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Evidence for Recent Liquid W
…
PIA01038
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Channels and Aprons in East Gorgonum Crater |
| Original Caption Released with Image |
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 (above left) is a composite of three different high resolution MOC views obtained in 1999 and 2000. The second picture (above 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 (above 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. |
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Evidence for Recent Liquid W
…
PIA01038
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Channels and Aprons in East Gorgonum Crater |
| Original Caption Released with Image |
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 (above left) is a composite of three different high resolution MOC views obtained in 1999 and 2000. The second picture (above 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 (above 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. |
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Evidence for Recent Liquid W
…
PIA01038
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Channels and Aprons in East Gorgonum Crater |
| Original Caption Released with Image |
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 (above left) is a composite of three different high resolution MOC views obtained in 1999 and 2000. The second picture (above 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 (above 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. |
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Evidence for Recent Liquid W
…
PIA01038
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Channels and Aprons in East Gorgonum Crater |
| Original Caption Released with Image |
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 (above left) is a composite of three different high resolution MOC views obtained in 1999 and 2000. The second picture (above 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 (above 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. |
|
Evidence for Recent Liquid W
…
PIA01038
Sol (our sun)
Mars Orbiter Camera
| Title |
Evidence for Recent Liquid Water on Mars: Channels and Aprons in East Gorgonum Crater |
| Original Caption Released with Image |
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 (above left) is a composite of three different high resolution MOC views obtained in 1999 and 2000. The second picture (above 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 (above 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. |
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Cydonia: Two Years Later
PIA02383
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
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Cydonia: Two Years Later
PIA02385
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
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Cydonia: Two Years Later
PIA02382
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
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Cydonia: Two Years Later
PIA02384
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
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Cydonia: Two Years Later
PIA02389
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
|
Cydonia: Two Years Later
PIA02387
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
|
Cydonia: Two Years Later
PIA02388
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
|
Cydonia: Two Years Later
PIA02386
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
|
Cydonia: Two Years Later
PIA02386
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
|
Cydonia: Two Years Later
PIA02386
Sol (our sun)
Mars Orbiter Camera
| Title |
Cydonia: Two Years Later |
| Original Caption Released with Image |
The recent motion picture, "Mission to Mars," takes as part of its premise that certain features in the Cydonia region of Mars were constructed as monuments by ancient Martians. This idea--widely popularized in books, magazines, tabloids and other news/infotainment media--has its origin in the chance observation (in 1976) by one of the Viking Orbiter spacecraft of a face-like hill. On April 5, 1998, the Mars Global Surveyor (MGS) spacecraft performed a specially-planned maneuver to photograph the "Face on Mars." Having successfully imaged the "Face" on its first attempt, two additional maneuvers were used to observe other purported "artificial" features: the "City" (a cluster of small mountains west-southwest of the "Face") and the "City Square" (a group of four small hills surrounded by the larger mountains of the "City"). These special observations occurred during the Science Phasing Orbits period of the MGS mission, while the spacecraft was in a 12 hour, elliptical orbit. A year later, in March 1999, MGS attained its final, circular, polar Mapping Orbit, from which it has now subsequently observed the planet for a year. During this year of mapping, the Mars Orbiter Camera (MOC) has continued to make observations within the Cydonia region whenever the MGS spacecraft has flown over that area. Click on Image for Full Resolution View Warning: This image is very large. The above figure shows the location of all high resolution (narrow angle) MOC images of the Cydonia region that have been obtained to date, including the first three taken in 1998 (PIA01240 [ http://photojournal.jpl.nasa.gov/catalog/PIA01240 ], PIA01241 [ http://photojournal.jpl.nasa.gov/catalog/PIA01241 ], AND PIA01440 [ http://photojournal.jpl.nasa.gov/catalog/PIA01440 ]). These images are superimposed upon a mosaic of Viking images taken during the 1970's. Images acquired during the Science Phasing Orbit period of 1998 slant from bottom left to top right, Mapping Phase images (from 1999 and 2000) slant from lower right to upper left. Owing to the nature of the orbit, and in particular to the limitations on controlling the location of the orbit, the longitudinal distribution of images (left/right in the images above) is distinctly non-uniform. An attempt to take a picture of a portion of the "Face" itself in mid-February 2000 was foiled when the MGS spacecraft experienced a sequencing error and most of that day's data were not returned to Earth. Only the first 97 lines were received, the image's planned footprint is shown as a dashed box. This image is one in a series of eight. |
|
White Rock' of Pollack Crate
…
PIA02848
Sol (our sun)
Mars Orbiter Camera
| Title |
White Rock' of Pollack Crater |
| Original Caption Released with Image |
"White Rock" is a ridged mound that was first seen and informally named "White Rock" in pictures from the Mariner 9 orbiter in 1972. In black-and-white photos, the feature appears much brighter than its surrounding terrain, giving the impression that the material is white. Later analyses of Mariner 9, Viking, and Mars Global Surveyor (MGS) data showed that the feature isn't actually white, it is somewhat red and reflects only about 20-25% of the sunlight that falls upon it (a white surface would reflect 100%). Located in Pollack Crater, a 95 km (59 mile) wide impact basin at 7.9°S, 334.7°W, White Rock is the light-red/orange feature with the rectangular white box drawn on it in the context view above. The white box indicates the location of a sub-frame of a MGS Mars Orbiter Camera (MOC) image acquired in September 2000, shown in the release image. The light-toned material that gives White Rock its name forms steep cliffs with valleys between them covered by dark, windblown, rippled sand. PIA02849 [ http://photojournal.jpl.nasa.gov/catalog/PIA02849 ] shows a close-up of a portion of this release, illustrating that the bright material is layered (arrow, "layers") and that there is an old impact crater (arrow, "crater") that has been partly uncovered from beneath the White Rock material. The layering in White Rock suggests that the material is sediment deposited at some time in the distant past within Pollack Crater. The fact that the material erodes to form steep cliffs suggests that it is hard like rock. Thus, White Rock is interpreted to be an outcrop of sedimentary rock. It is probably a small remnant of a larger body of rock that may have once covered the entire floor of Pollack Crater, this view is supported by the observation that more extensive layered rocks are seen in other craters across the surface of the red planet (e.g., the crater at 8°N, 7°W). Both pictures shown here are illuminated by sunlight from the upper left, north is up. Pollack Crater was named in 1997 for James B. Pollack (1938-1994), a NASA Ames Research Center scientist known in the Mars research community for his atmospheric research with Mariner 9 and Viking data and the development of key computer models used to investigate the red planet's winds, storms, and climate. |
|
White Rock' of Pollack Crate
…
PIA02849
Sol (our sun)
Mars Orbiter Camera
| Title |
White Rock' of Pollack Crater |
| Original Caption Released with Image |
"White Rock" is a ridged mound that was first seen and informally named "White Rock" in pictures from the Mariner 9 orbiter in 1972. In black-and-white photos, the feature appears much brighter than its surrounding terrain, giving the impression that the material is white. Later analyses of Mariner 9, Viking, and Mars Global Surveyor (MGS) data showed that the feature isn't actually white, it is somewhat red and reflects only about 20-25% of the sunlight that falls upon it (a white surface would reflect 100%). Located in Pollack Crater, a 95 km (59 mile) wide impact basin at 7.9°S, 334.7°W, White Rock is the light-red/orange feature with the rectangular white box drawn on it in the context view above. The white box indicates the location of a sub-frame of a MGS Mars Orbiter Camera (MOC) image acquired in September 2000, shown in PIA02848 [ http://photojournal.jpl.nasa.gov/catalog/PIA02848 ]. The light-toned material that gives White Rock its name forms steep cliffs with valleys between them covered by dark, windblown, rippled sand. This release image shows a close-up of a portion of PIA02848 [ http://photojournal.jpl.nasa.gov/catalog/PIA02848 ], illustrating that the bright material is layered (arrow, "layers") and that there is an old impact crater (arrow, "crater") that has been partly uncovered from beneath the White Rock material. The layering in White Rock suggests that the material is sediment deposited at some time in the distant past within Pollack Crater. The fact that the material erodes to form steep cliffs suggests that it is hard like rock. Thus, White Rock is interpreted to be an outcrop of sedimentary rock. It is probably a small remnant of a larger body of rock that may have once covered the entire floor of Pollack Crater, this view is supported by the observation that more extensive layered rocks are seen in other craters across the surface of the red planet (e.g., the crater at 8°N, 7°W). Both pictures shown here are illuminated by sunlight from the upper left, north is up. Pollack Crater was named in 1997 for James B. Pollack (1938-1994), a NASA Ames Research Center scientist known in the Mars research community for his atmospheric research with Mariner 9 and Viking data and the development of key computer models used to investigate the red planet's winds, storms, and climate. |
|
White Rock' of Pollack Crate
…
PIA02849
Sol (our sun)
Mars Orbiter Camera
| Title |
White Rock' of Pollack Crater |
| Original Caption Released with Image |
"White Rock" is a ridged mound that was first seen and informally named "White Rock" in pictures from the Mariner 9 orbiter in 1972. In black-and-white photos, the feature appears much brighter than its surrounding terrain, giving the impression that the material is white. Later analyses of Mariner 9, Viking, and Mars Global Surveyor (MGS) data showed that the feature isn't actually white, it is somewhat red and reflects only about 20-25% of the sunlight that falls upon it (a white surface would reflect 100%). Located in Pollack Crater, a 95 km (59 mile) wide impact basin at 7.9°S, 334.7°W, White Rock is the light-red/orange feature with the rectangular white box drawn on it in the context view above. The white box indicates the location of a sub-frame of a MGS Mars Orbiter Camera (MOC) image acquired in September 2000, shown in PIA02848 [ http://photojournal.jpl.nasa.gov/catalog/PIA02848 ]. The light-toned material that gives White Rock its name forms steep cliffs with valleys between them covered by dark, windblown, rippled sand. This release image shows a close-up of a portion of PIA02848 [ http://photojournal.jpl.nasa.gov/catalog/PIA02848 ], illustrating that the bright material is layered (arrow, "layers") and that there is an old impact crater (arrow, "crater") that has been partly uncovered from beneath the White Rock material. The layering in White Rock suggests that the material is sediment deposited at some time in the distant past within Pollack Crater. The fact that the material erodes to form steep cliffs suggests that it is hard like rock. Thus, White Rock is interpreted to be an outcrop of sedimentary rock. It is probably a small remnant of a larger body of rock that may have once covered the entire floor of Pollack Crater, this view is supported by the observation that more extensive layered rocks are seen in other craters across the surface of the red planet (e.g., the crater at 8°N, 7°W). Both pictures shown here are illuminated by sunlight from the upper left, north is up. Pollack Crater was named in 1997 for James B. Pollack (1938-1994), a NASA Ames Research Center scientist known in the Mars research community for his atmospheric research with Mariner 9 and Viking data and the development of key computer models used to investigate the red planet's winds, storms, and climate. |
|
White Rock' of Pollack Crate
…
PIA02849
Sol (our sun)
Mars Orbiter Camera
| Title |
White Rock' of Pollack Crater |
| Original Caption Released with Image |
"White Rock" is a ridged mound that was first seen and informally named "White Rock" in pictures from the Mariner 9 orbiter in 1972. In black-and-white photos, the feature appears much brighter than its surrounding terrain, giving the impression that the material is white. Later analyses of Mariner 9, Viking, and Mars Global Surveyor (MGS) data showed that the feature isn't actually white, it is somewhat red and reflects only about 20-25% of the sunlight that falls upon it (a white surface would reflect 100%). Located in Pollack Crater, a 95 km (59 mile) wide impact basin at 7.9°S, 334.7°W, White Rock is the light-red/orange feature with the rectangular white box drawn on it in the context view above. The white box indicates the location of a sub-frame of a MGS Mars Orbiter Camera (MOC) image acquired in September 2000, shown in PIA02848 [ http://photojournal.jpl.nasa.gov/catalog/PIA02848 ]. The light-toned material that gives White Rock its name forms steep cliffs with valleys between them covered by dark, windblown, rippled sand. This release image shows a close-up of a portion of PIA02848 [ http://photojournal.jpl.nasa.gov/catalog/PIA02848 ], illustrating that the bright material is layered (arrow, "layers") and that there is an old impact crater (arrow, "crater") that has been partly uncovered from beneath the White Rock material. The layering in White Rock suggests that the material is sediment deposited at some time in the distant past within Pollack Crater. The fact that the material erodes to form steep cliffs suggests that it is hard like rock. Thus, White Rock is interpreted to be an outcrop of sedimentary rock. It is probably a small remnant of a larger body of rock that may have once covered the entire floor of Pollack Crater, this view is supported by the observation that more extensive layered rocks are seen in other craters across the surface of the red planet (e.g., the crater at 8°N, 7°W). Both pictures shown here are illuminated by sunlight from the upper left, north is up. Pollack Crater was named in 1997 for James B. Pollack (1938-1994), a NASA Ames Research Center scientist known in the Mars research community for his atmospheric research with Mariner 9 and Viking data and the development of key computer models used to investigate the red planet's winds, storms, and climate. |
|
South Polar Cap
| title |
South Polar Cap |
| Description |
This is the south polar cap of Mars as it appeared to the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) on April 17, 2000. In winter and early spring, this entire scene would be covered by frost. In summer, the cap shrinks to its minimum size, as shown here. Even though it is summer, observations made by the Viking orbiters in the 1970s showed that the south polar cap remains cold enough that the polar frost (seen here as white) consists of carbon dioxide. Carbon dioxide freezes at temperatures around -125° C (-193° F). Mid-summer afternoon sunlight illuminates this scene from the upper left from about 11.2° above the horizon. Soon the cap will experience sunsets, by June 2000, this pole will be in autumn, and the area covered by frost will begin to grow. Winter will return to the south polar region in December 2000. The polar cap from left to right is about 420 km (260 mi) across. Photo Credit: NASA/JPL/Malin Space Science Systems |
|
South Polar Cap, Summer 2000
PIA02393
Sol (our sun)
Mars Orbiter Camera
| Title |
South Polar Cap, Summer 2000 |
| Original Caption Released with Image |
This is the south polar cap of Mars as it appeared to the Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) on April 17, 2000. In winter and early spring, this entire scene would be covered by frost. In summer, the cap shrinks to its minimum size, as shown here. Even though it is summer, observations made by the Viking orbiters in the 1970s showed that the south polar cap remains cold enough that the polar frost (seen here as white) consists of carbon dioxide. Carbon dioxide freezes at temperatures around -125° C (-193° F). Mid-summer afternoon sunlight illuminates this scene from the upper left from about 11.2° above the horizon. Soon the cap will experience sunsets, by June 2000, this pole will be in autumn, and the area covered by frost will begin to grow. Winter will return to the south polar region in December 2000. The polar cap from left to right is about 420 km (260 mi) across. |
|
Light-toned Layered Outcrops
…
PIA02847
Sol (our sun)
Mars Orbiter Camera
| Title |
Light-toned Layered Outcrops in Valles Marineris Walls |
| Original Caption Released with Image |
Valles Marineris a system of troughs, chasms, and pit chains that stretches more than 4,000 km (2,500 miles) across the martian western hemisphere. Outcrops of layered material found in mounds and mesas within the chasms of the Valles Marineris were known from the pictures taken by Mariner 9 in 1972 and the Viking orbiters of 1976-1980. One example of the those known previously is the mesa labeled "Candor Mensa" in the context image (above), another example is the mound in the center of Ganges Chasma. For several decades, it has been widely speculated among Mars scientists that the light- and dark-toned layered materials in the Valles Marineris might have formed in lakes that had once filled the chasms during the most recent epoch of martian history, others thought they might result from volcanic ash deposited in the chasms. Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) images have confirmed the presence of light- and dark-toned layered sedimentary rock outcrops in the Valles Marineris, but they have also revealed many more than were previously known and they have shown several good examples that these materials are coming out of the walls of the Valles Marineris chasms. The fact that these materials come out of the chasm walls means that the layers do not represent lakes (or volcanic debris) that formed in the Valles Marineris. Instead, they represent materials deposited and buried long before there ever was a Valles Marineris. They are seen now because of the faulting and erosion that opened up and widened the Valles Marineris troughs. The context image is a mosaic of Viking 1 orbiter images taken in 1976 showing a portion of the wall that separates western Ophir Chasma from western Candor Chasma in the Valles Marineris. This area is located around 5°S, 74°W. The white box labeled "M17-00467" shows the location of a subframe of MOC image M17-00467 that was acquired in July 2000 to allow scientists to examine one of the many bright patches (indicated by small arrows) seen on the walls of Valles Marineris. The release image is a subframe of MOC image M17-00467, showing a high-resolution view of one of the bright patches on the walls of Candor Chasma. The MOC image reveals that the bright material indeed consists of light-toned layered rock similar to other outcrops thought to be sedimentary in origin found throughout the Valles Marineris. The dark ridge running from top center to center-left in this view is mantled by a smooth, dark material that covers additional light-toned layered rock. The observation that these kinds of bright layered rock occur within the walls of the Valles Marineris indicate that the materials are very, very old. They have been buried under several kilometers (i.e., more than a mile) of additional layered rock, all of which is beneath plains thought to be more than 2.5 to 3.5 billion years old. These relationships suggest that all of the layered sedimentary rocks observed on Mars by MGS MOC may date back to the, earliest parts of martian history, between 3.5 and 4.5 billion years ago. In both pictures, north is toward the top. Sunlight illuminates the context image from the top/right, the MOC image (top left) is illuminated from the upper left. |
|
Light-toned Layered Outcrops
…
PIA02847
Sol (our sun)
Mars Orbiter Camera
| Title |
Light-toned Layered Outcrops in Valles Marineris Walls |
| Original Caption Released with Image |
Valles Marineris a system of troughs, chasms, and pit chains that stretches more than 4,000 km (2,500 miles) across the martian western hemisphere. Outcrops of layered material found in mounds and mesas within the chasms of the Valles Marineris were known from the pictures taken by Mariner 9 in 1972 and the Viking orbiters of 1976-1980. One example of the those known previously is the mesa labeled "Candor Mensa" in the context image (above), another example is the mound in the center of Ganges Chasma. For several decades, it has been widely speculated among Mars scientists that the light- and dark-toned layered materials in the Valles Marineris might have formed in lakes that had once filled the chasms during the most recent epoch of martian history, others thought they might result from volcanic ash deposited in the chasms. Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) images have confirmed the presence of light- and dark-toned layered sedimentary rock outcrops in the Valles Marineris, but they have also revealed many more than were previously known and they have shown several good examples that these materials are coming out of the walls of the Valles Marineris chasms. The fact that these materials come out of the chasm walls means that the layers do not represent lakes (or volcanic debris) that formed in the Valles Marineris. Instead, they represent materials deposited and buried long before there ever was a Valles Marineris. They are seen now because of the faulting and erosion that opened up and widened the Valles Marineris troughs. The context image is a mosaic of Viking 1 orbiter images taken in 1976 showing a portion of the wall that separates western Ophir Chasma from western Candor Chasma in the Valles Marineris. This area is located around 5°S, 74°W. The white box labeled "M17-00467" shows the location of a subframe of MOC image M17-00467 that was acquired in July 2000 to allow scientists to examine one of the many bright patches (indicated by small arrows) seen on the walls of Valles Marineris. The release image is a subframe of MOC image M17-00467, showing a high-resolution view of one of the bright patches on the walls of Candor Chasma. The MOC image reveals that the bright material indeed consists of light-toned layered rock similar to other outcrops thought to be sedimentary in origin found throughout the Valles Marineris. The dark ridge running from top center to center-left in this view is mantled by a smooth, dark material that covers additional light-toned layered rock. The observation that these kinds of bright layered rock occur within the walls of the Valles Marineris indicate that the materials are very, very old. They have been buried under several kilometers (i.e., more than a mile) of additional layered rock, all of which is beneath plains thought to be more than 2.5 to 3.5 billion years old. These relationships suggest that all of the layered sedimentary rocks observed on Mars by MGS MOC may date back to the, earliest parts of martian history, between 3.5 and 4.5 billion years ago. In both pictures, north is toward the top. Sunlight illuminates the context image from the top/right, the MOC image (top left) is illuminated from the upper left. |
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Light-toned Layered Outcrops
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PIA02847
Sol (our sun)
Mars Orbiter Camera
| Title |
Light-toned Layered Outcrops in Valles Marineris Walls |
| Original Caption Released with Image |
Valles Marineris a system of troughs, chasms, and pit chains that stretches more than 4,000 km (2,500 miles) across the martian western hemisphere. Outcrops of layered material found in mounds and mesas within the chasms of the Valles Marineris were known from the pictures taken by Mariner 9 in 1972 and the Viking orbiters of 1976-1980. One example of the those known previously is the mesa labeled "Candor Mensa" in the context image (above), another example is the mound in the center of Ganges Chasma. For several decades, it has been widely speculated among Mars scientists that the light- and dark-toned layered materials in the Valles Marineris might have formed in lakes that had once filled the chasms during the most recent epoch of martian history, others thought they might result from volcanic ash deposited in the chasms. Mars Global Surveyor (MGS) Mars Orbiter Camera (MOC) images have confirmed the presence of light- and dark-toned layered sedimentary rock outcrops in the Valles Marineris, but they have also revealed many more than were previously known and they have shown several good examples that these materials are coming out of the walls of the Valles Marineris chasms. The fact that these materials come out of the chasm walls means that the layers do not represent lakes (or volcanic debris) that formed in the Valles Marineris. Instead, they represent materials deposited and buried long before there ever was a Valles Marineris. They are seen now because of the faulting and erosion that opened up and widened the Valles Marineris troughs. The context image is a mosaic of Viking 1 orbiter images taken in 1976 showing a portion of the wall that separates western Ophir Chasma from western Candor Chasma in the Valles Marineris. This area is located around 5°S, 74°W. The white box labeled "M17-00467" shows the location of a subframe of MOC image M17-00467 that was acquired in July 2000 to allow scientists to examine one of the many bright patches (indicated by small arrows) seen on the walls of Valles Marineris. The release image is a subframe of MOC image M17-00467, showing a high-resolution view of one of the bright patches on the walls of Candor Chasma. The MOC image reveals that the bright material indeed consists of light-toned layered rock similar to other outcrops thought to be sedimentary in origin found throughout the Valles Marineris. The dark ridge running from top center to center-left in this view is mantled by a smooth, dark material that covers additional light-toned layered rock. The observation that these kinds of bright layered rock occur within the walls of the Valles Marineris indicate that the materials are very, very old. They have been buried under several kilometers (i.e., more than a mile) of additional layered rock, all of which is beneath plains thought to be more than 2.5 to 3.5 billion years old. These relationships suggest that all of the layered sedimentary rocks observed on Mars by MGS MOC may date back to the, earliest parts of martian history, between 3.5 and 4.5 billion years ago. In both pictures, north is toward the top. Sunlight illuminates the context image from the top/right, the MOC image (top left) is illuminated from the upper left. |
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Evidence for Recent Liquid W
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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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Evidence for Recent Liquid W
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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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Evidence for Recent Liquid W
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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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Evidence for Recent Liquid W
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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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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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Newton Crater
| title |
Newton Crater |
| Description |
Newton Crater is a large basin formed by an asteroid impact that probably occurred more than 3 billion years ago. It is approximately 287 kilometers (178 miles) across. The picture shown here (top) highlights the north wall of a specific, smaller crater located in the southwestern quarter of Newton Crater (above). The crater of interest was also formed by an impact, it is about 7 km (4.4 mi) across, which is about 7 times bigger than the famous Meteor Crater in northern Arizona in North America. The north wall of the small crater has many narrow gullies eroded into it. These are hypothesized to have been formed by flowing water and debris flows. Debris transported with the water created lobed and finger-like deposits at the base of the crater wall where it intersects the floor (bottom center top image). Many of the finger-like deposits have small channels indicating that a liquid--most likely water--flowed in these areas. Hundreds of individual water and debris flow events might have occurred to create the scene shown here. Each outburst of water from higher up on the crater slopes would have constituted a competition between evaporation, freezing, and gravity. The individual deposits at the ends of channels in this MOC image mosaic were used to get a rough estimate of the minimum amount of water that might be involved in each flow event. This is done first by assuming that the deposits are like debris flows on Earth. In a debris flow, no less than about 10% (and no more than 30%) of their volume is water. Second, the volume of an apron deposit is estimated by measuring the area covered in the MOC image and multiplying it by a conservative estimate of thickness, 2 meters (6.5 feet). For a flow containing only 10% water, these estimates conservatively suggest that about 2.5 million liters (660,000 gallons) of water are involved in each event, this is enough to fill about 7 community-sized swimming pools or enough to supply 20 people with their water needs for a year. The MOC high resolution view is located near 41.1°S, 159.8°W and is a mosaic of three different pictures acquired between January and May 2000. The MOC scene is illuminated from the left, north is up. The context picture was acquired in 1977 by the Viking 1 orbiter and is illuminated from the upper right. Photo Credit: NASA/JPL/Malin Space Science Systems |
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