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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's region is Valles Marineris. This image of Ius Chasma shows several landslide deposits and groups of sand dunes.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's region is Apollinaris Patera. Apollinaris Patera is an old volcano that has undergone extensive erosion. This volcano is located north of Gusev Crater, the home of the rover called Spirit. Part of the summit caldera is shown in this image.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's region is Apollinaris Patera. Apollinaris Patera is an old volcano that has undergone extensive erosion. This volcano is located north of Gusev Crater, the home of the rover called Spirit. Today's image is of the eroded southeastern flank of the volcano.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's region is Apollinaris Patera. Apollinaris Patera is an old volcano that has undergone extensive erosion. This volcano is located north of Gusev Crater, the home of the rover called Spirit. Today's image shows the boundary between the base of the volcano and the wind eroded materials located NNW of Apollinaris Patera.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's region is Apollinaris Patera. Apollinaris Patera is an old volcano that has undergone extensive erosion. This volcano is located north of Gusev Crater, the home of the rover called Spirit. Today's image shows the southwestern flank of the volcano.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's region is Apollinaris Patera. Apollinaris Patera is an old volcano that has undergone extensive erosion. This volcano is located north of Gusev Crater, the home of the rover called Spirit. Today's image shows the northwestern edge of the summit caldera.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's topic is medium sized channels. Verde Vallis has a realitively uniform width, but erosion of the walls has reduced the channel depth and makes the valley indistinct from its surroundings in some areas.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's topic is medium sized channels. Tinto Vallis is bounded by steep walls so its sinuous course is easy to identify and trace from image to image.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's topic is medium sized channels. The entire region surrounding Indus Vallis has undergone extensive erosion. The deepest part of the channel is still identifiable, but it is impossible to tell if the wider bounding walls represent a terraced portion of the original channel or just easily eroded materials.

Source: THEMIS - Mars Odyssey Mission

September 18, 2007


Artists concept of the 2001 Mars Odyssey Spacecraft

The team operating NASA's Mars Odyssey orbiter is returning the healthy spacecraft to usual activities this week after a precautionary status of reduced activity that the orbiter entered on Sept. 14.

Odyssey properly put itself into the standby "safe mode" in response to a root cause that engineers have diagnosed as the same cause as for two previous safe mode entries, in 2005 and 2006. When the onboard flight computer could not get a routine response from the system that monitors the spacecraft's orientation, a fault protection feature in the software told the flight computer to reboot and put the spacecraft into the standby status. In reality, the attitude-control task was operating just fine, but a messaging interface system got stuck, leaving the flight computer to assume the task was no longer running.

While in safe mode, Odyssey stayed in communication, with its main antenna pointed toward Earth and its solar panels facing the sun.

The ground team is returning the spacecraft to full service step by step. The spacecraft is expected to point its instruments and UHF relay antenna toward Mars today (Tuesday), to resume relaying communications from the Mars rovers on Wednesday, and to resume using its own science instruments on Thursday. The rovers are communicating directly with Earth while Odyssey is unavailable for relay.

"The spacecraft reacted exactly as it was designed to for this condition," said Odyssey Mission Manager Robert Mase of NASA's Jet Propulsion Laboratory, Pasadena, Calif. "The onboard autonomy ensures that the spacecraft keeps itself in a safe state and allows time for the ground teams to respond with the established contingency procedures that were designed for these circumstances."

JPL, a division of the California Institute of Technology, manages the Mars Odyssey project for the NASA Science Mission Directorate. The orbiter reached Mars in 2001 and is partway through its second mission extension.

Media contact: Guy Webster, 818-354-6278

Source: NASA/JPL - News - Feature Stories

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Detailed information on this image is available at the THEMIS Data Releases website.

The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's topic is medium sized channels. This image of Scamander Vallis contains several tributaries entering the main channel.

Source: THEMIS - Mars Odyssey Mission

On the southwest edge of the immense volcanic region of Tharsis, lava from its giant volcanoes flowed down to meet the old cratered landscape of Terra Sirenum. Scientists can't say how many years separate the flows from the terrain they engulfed, but the relationship between the two tells of a complex tale.

This false-color mosaic image combines separate frames taken by the Thermal Emission Imaging System (THEMIS), a special camera on NASA's Mars Odyssey orbiter. THEMIS photographs Mars in 10 infrared "colors" and five visible ones.

The infrared imaging gives scientists clues about the nature of the surface. THEMIS photographs patches of ground twice per Martian day - once in late afternoon and then again just before night ends - two times when contrasts in surface temperature are strongest.

Under full sunlight, dust, sand, and loose sediments grow warm, even hot, as anybody knows who has walked barefoot across a sunny beach. (Dark materials also do the same.) In the depths of night on Mars, however, fine particles quickly become cold as temperatures plunge after sundown. But rocky areas and ones with expanses of compacted sediments hold onto heat better and glow warmly in THEMIS' infrared vision.

In this false-color mosaic, THEMIS researchers have colored in blues and greens the areas that are cold at night, while nighttime-warm regions appear in reds, oranges, and yellows. The tints distinguish areas covered in dust and sand (cool colors) from exposures of bare rocks and deposits free of fine-grain material (warm colors).
Thumbnail 1

Flood

The close-up image at left shows a geological story with at least three episodes. The oldest appears in the buckled terrain at the bottom of the frame.

This sculptured slope is part of the outside wall of an impact crater 43 kilometers (27 miles) wide. The crater formed early in the oldest period of Martian history, the Noachian, which lasted from the planet's formation (4.6 billion years ago) until about 3.8 billion years ago.

Since the impact, the crater rim materials have accumulated a coating of fine-grain debris. This causes the ground to appear blue in the false-color image because the materials are cold by the time THEMIS passes overhead late at night.

Some time after the meteorite strike that made the crater, lava flows buried the rumpled blanket of ejected debris that originally surrounded the crater, erasing it right up to the foot of the crater-rim. This flow appears in the center of the frame as a flat surface tinted blue, thanks to its dusty covering. It lies sandwiched between lobes of younger, rockier lava flows tinted yellow and orange.

The younger flows mark the third geological episode. They are about 40 meters (130 feet) thick as seen here, but thicknesses vary across the region. It's easy to trace the youngest flows, which lack a covering of cold dust and sand.

Both episodes of lava flooding, old and new, form part of the vast Daedalia Planum region, a huge lava sheet made of countless individual streams and flows. Daedalia spreads south from Arsia Mons, the southernmost of the giant volcanoes of Tharsis.

Scientists think Tharsis began to build in the late Noachian and continued to develop in the Hesperian, the middle period of Martian history. This spanned between roughly 3.8 and 3.0 billion years ago. Finally, the great volcanoes themselves culminated in the Amazonian, the current Martian geological period.
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Stretch

Lava sheets are broad, thin, and brittle. The floor of the channel here lies about 50 m (160 ft) below the surface of the flow, and forms what geologists call a graben (grah-ben). It spreads about 2 km (1.2 mi) wide here.

This graben isn't the only one in the area. A look at the big mosaic shows traces of other grabens, all trending in a southwest-northeast direction. And looking even farther afield, scientists note more grabens with much the same directional trend where the Terra Sirenum highlands descend to meet the lava flows of Daedalia.

What's going on? The grabens are not aligned by chance; instead, they reflect geological stresses at work across the whole Daedalia region. And the driving source, say most researchers, is Arsia Mons, the big Tharsis volcano that lies 1,700 km (1,100 mi) to the northeast.

If the grabens are like bicycle spokes, the wheel hub lies at the volcano's summit. As scientists reconstruct it, the grabens show where fresh lava forced itself upward along faults that run radial to Arsia Mons. As lava rose along the faults, the brittle, cold lava at the surface cracked as it tried to spread, and shallow troughs developed above the fault lines.
Thumbnail 3

Overflow

The floods of lava that spilled across the Daedalia plains lapped all around the large crater. And some lava leaked inside, either over the rim or upward through the shattered rocks directly under the crater.

In fact, both processes could have happened. The floor of the crater (upper left) lies 1,000 m (3,300 ft) below the plains outside the rim (lower right). A narrow stream of rocky material crept over the top of the rim and ran down the inside wall, as seen in the close-up at left.

In contrast, the broad tongue of light-tinted material, which stands about 40 meters (130 ft) higher than the crater floor, probably has a different origin. It may simply be a landslide that came down the inner rim wall and spilled across the part of the floor, burying fresh, blocky lava.

The feature might also be remnant of an earlier stage of lava flooding (like the older flows on the plains outside). Or it may be a leftover part of the pool of molten rock that filled the crater floor immediately after the impact. If so, it stood too high to be inundated completely by the later lava flow.

Source: THEMIS - Mars Odyssey Mission - Features

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Detailed information on this image is available at the THEMIS Data Releases website.
The major Martian dust storm of 2007 filled the sky with dust and produced conditions that prevented the THEMIS VIS camera from being able to image the surface. With no new images being acquired, we've dug into the archive to highlight some interesting areas on Mars. The this week's topic is medium sized channels. Her Desher Vallis is the final medium-sized channel this week.

Source: THEMIS - Mars Odyssey Mission

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This infrared image shows half of Ulysses Patera.

Source: THEMIS - Mars Odyssey Mission

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This VIS image was collected during the major Martian dust storm of 2007. The amount of dust filled atmosphere was thinner over the high altitude summits of the Tharsis volcanoes. This image shows the summit of Arsia Mons.

Source: THEMIS - Mars Odyssey Mission

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This VIS image was collected during the major Martian dust storm of 2007. The amount of dust filled atmosphere was thinner over the high altitude summits of the Tharsis volcanoes. This image shows the summit of Ascraeus Mons.

Source: THEMIS - Mars Odyssey Mission

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This VIS image was collected during the major Martian dust storm of 2007. The amount of dust filled atmosphere was thinner over the high altitude summits of the Tharsis volcanoes. This image shows the summit of Olympus Mons.

Source: THEMIS - Mars Odyssey Mission

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This VIS image shows the summit of Biblis Patera.

Source: THEMIS - Mars Odyssey Mission

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This VIS image shows part of the summit caldera and south-eastern flank of Ulysses Patera.

Source: THEMIS - Mars Odyssey Mission

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This VIS image shows a small part of the summit caldera of Uranius Patera.

Source: THEMIS - Mars Odyssey Mission

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This VIS image crosses Biblis Patera. Note the large size and depth of the summit caldera in relation to the size of the entire construct.

Source: THEMIS - Mars Odyssey Mission

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This VIS image shows lava flows on the eastern flank of Olympus Mons.

Source: THEMIS - Mars Odyssey Mission

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This infrared image shows part of Noctis Labyrinthus and the volcanic plains to the south. A large landslide covers the floor of one of the canyons.

Source: THEMIS - Mars Odyssey Mission

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The Medusa Fossae Formation is located east of the Tharsis volcanoes. The material(s) of the formation are easily eroded by the wind and many different wind sculpted textures are found in images of this region.

Source: THEMIS - Mars Odyssey Mission

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The Medusa Fossae Formation is located east of the Tharsis volcanoes. The material(s) of the formation are easily eroded by the wind and many different wind sculpted textures are found in images of this region.

Source: THEMIS - Mars Odyssey Mission

Syrtis Major is a large dark region on Mars visible from Earth even in small telescopes. Its darkness comes from lava flows free of dust, for Syrtis is a gigantic, windswept volcano. Rising only slightly above its surroundings, Syrtis spans more than 1,300 kilometers (800 miles) wide.

Just north of Syrtis, the Martian highlands end in a region called Nilosyrtis. Here the highlands break up into isolated peaks and mesas in a transition zone scientists call the crustal dichotomy. This is a relatively abrupt change in elevation - a drop averaging 5,500 meters (18,000 feet) - that encircles the planet, marking a boundary between the highlands to the south and the vast lowlands that cap the northern half of Mars.

These scene here shows part of the edge where the highlands are disappearing. On the left is a large, ruined crater about 90 km (55 mi) wide and roughly 3,000 m (10,000 ft) deep. Layers of sedimentary deposits fill its floor and line the channels between the hills and mesas that extend downward toward the east (right) into the lowlands.

In the dead center of the frame, where the crater's northeastern wall would lie, is a candidate landing site for NASA's next Mars rover, the Mars Science Laboratory, or MSL.

MSL's mission is to find deposits that will tell scientists if Mars has ever been a home for microbial life. The Nilosyrtis site caught scientists' interest because in places its sedimentary layers contain water-altered clay minerals called phyllosilicates. These may preserve traces of ancient life.

Nilosyrtis is one of a number of potential landing sites which scientists hope to narrow down to just a handful. Then, careful study using spacecraft already at Mars will reduce this handful to a prime site plus a backup or two by the time MSL launches in September 2009.

This mosaic of the Nilosyrtis site merges numerous frames made by the Thermal Emission Imaging System (THEMIS), a multi-band camera on NASA's Mars Odyssey orbiter. THEMIS researchers combined daytime and nighttime infrared views to create a false-color mosaic that shows the nature of the Martian surface.

In essence, areas covered with dust, sand, and fine grain particles appear in tones of blues and greens. Harder sediments and outcrops of rock, however, show in shades of yellow, orange, and red.

Ground Zero


The center of MSL's circular landing zone (20 km or 12 mi in diameter) lies at the center of the close-up image at left, which is 35 km (22 mi) square. The hill at the top of the closeup image rises about 600 m (2,000 ft) above the landing zone's elevation.

The landing zone and its immediate surroundings were selected as a candidate because they contain sediments identified as phyllosilicates by scientists using the OMEGA instrument on the European Space Agency's orbiter, Mars Express.

The existence of phyllosilicate minerals indicates that water was present in the ground at some point. Water is essential to life on Earth and, presumably, would have been equally essential in any Martian biosphere. Thus the search for possible ancient habitats on Mars revolves around places that show evidence for water's effects.

But science is only half of the story: First, the lander has to get down safely. According to high-resolution images from NASA's Mars Reconnaissance Orbiter, the ground at the landing site appears relatively flat and neither too dusty nor too rocky.

MSL is designed with a minimum driving range of 20 km (12 mi), and with any luck, it should far exceed that. Thus even if the rover were to land on a scientifically less-interesting piece of ground, mission controllers can drive off in search of a better one to study.

Long Mesa


One interesting site lies about 20 km to the northeast of the landing zone. This long, flat-topped ridge, about 200 m (700 ft) high, is likely a remnant of a layer (or several layers) that once covered a much greater area.
Nilo Syrtis Inset Image


DEBRIS SLOPE. Rocks and deposits
from a high mesa near the MSL landing site
have collected in a jumble at the foot of the
mesa's slopes.
(Credit: NASA/JPL/University of Arizona)

On Earth such features give geologists a detailed look at a sequence of rock layers, with the oldest at bottom and the youngest on top. Such layers always open a window into Earth's history, and the same surely holds for Mars as well.

Close-up images (such as at right) taken by the HiRISE camera on the Mars Reconnaissance Orbiter show the long mesa flanked with debris that has weathered out of the mesa's layers and accumulated at the foot of the slope.

MSL might never visit this mesa - and its upper layers might also prove too steep for MSL to climb - but the rover could explore the rubble around the base of the mesa. This would let scientists study rock layers that remain out of reach on the slopes above.

History Book


Another "history book" of sediments lies within a nearly filled crater at the bottom of the big mosaic. This crater is about 70 km (45 mi) wide and 2,000 m (6,500 ft) deep. Its northern rim is sliced open by a deep channel that descends to the Nilosyrtis floor.
Nilo Syrtis Inset Image


TORN PAGES. Blocks of sediments
within the crater testify to bygone eras
when the crater may have been held a
lake. Thin, blade-like ridges show where
harder minerals collected in cracks and
faults and then emerged as softer
surrounding sediments wasted away.
(Credit: NASA/JPL/Arizona State University)

At one point in the Martian past, this crater must have been brimming with water. Some event caused the water to overflow the rim to the north, and erosion promptly cut the channel, which widened and deepened as the draining flow continued.

At greatest, the channel is 15 km (9 mi) wide and 1,000 m (3,300 ft) deep. Its snaking course runs for 60 km (37 mi).

As the waters drained, they left behind layers of sediments that may have accumulated when a lake filled the crater. The floor of the crater is divided into blocks and hills (see the THEMIS visible wavelength image at right) that stand 50 to 100 m (150 to 330 ft) high, separated by channels filled with fine-grain deposits.

As with all sedimentary layers, the blocks will preserve chemical and physical features that could tell scientists much about the time when they formed.

The chances of MSL ever driving up the big channel and into the crater are remote, to say the least. But if it happens, the rover will open a new chapter in the book of Martian geological history.

Source: THEMIS - Mars Odyssey Mission - Features

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The Medusa Fossae Formation is located east of the Tharsis volcanoes. The material(s) of the formation are easily eroded by the wind and many different wind sculpted textures are found in images of this region.

Source: THEMIS - Mars Odyssey Mission

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Context image credit: NASA/JPL/MOLA
View on map

The Medusa Fossae Formation is located east of the Tharsis volcanoes. The material(s) of the formation are easily eroded by the wind and many different wind sculpted textures are found in images of this region.

The hill at the bottom of this image is the same hill at the top of tomorrow's image.

Source: THEMIS - Mars Odyssey Mission

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Context image credit: NASA/JPL/MOLA
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The Medusa Fossae Formation is located east of the Tharsis volcanoes. The material(s) of the formation are easily eroded by the wind and many different wind sculpted textures are found in images of this region.

The hill at the top of this image is the same hill from the bottom of yesterday's image.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

This VIS image contains an island in Tiu Valles. The impact crater divided the flow along both sides, wearing away the upstream ejecta and depositing a "tail" of material downstream.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

Just like yesterday's crater, this crater was an obstacle to material flowing around it. In this case the material is lava from the Arsia Mons volcano. The diverted flows formed a downhill "tail" south of the crater. This "tail" is a depression where lava failed to fill in the region behind the crater.

Source: THEMIS - Mars Odyssey Mission

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Detailed information on this image is available at the THEMIS Data Releases website.

This image shows a small protion of Zephyris Planum, a region south of Elysium Planitia. Winds have scoured the region removing loose materials and scultping the rocks.

Source: THEMIS - Mars Odyssey Mission