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Sunday, April 6, 2014

Small Pale Red Planet Issue 4 Phase 2

 

The Thaumasia Region

MC-25

 

The Thaumasia Region covers the area from 60° to 120° west longitude and 30° to 65° south latitude on Mars. One of the first major networks of stream channels, called Warrego Valles, were discovered here by early orbiters. Another sign of water is the presence of gullies carved into steep slopes. The highest elevations are red and the lowest are blue.

 

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Topographical Map of the Thaumasia Region

Although many ideas have been put forward to explaining Martian gullies, the most popular involve liquid water coming from an aquifer, from melting at the base of old glaciers, or from the melting of ice in the ground when the climate was warmer. Because of the good possibility that liquid water was involved with their formation and that they could be very young, scientists are excited. Maybe the gullies are where we should go to find life.

 

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Image of Thaumasia Region

The northern part of this Region includes Thaumasia plateau. The southern part contains heavily cratered highland terrain and relatively smooth, low plains. The east-central part includes Lowell Crater.

As  usual we begin our survey from the northeast corner of the Region.  We first encounter the Icaria Planum in the northeast area of the Region bordered on the east by the Claritas Rupes and the Claritas Fossae further south.

 

The Icaria Planum is a region on Mars in the Thaumasia Region of Mars that is 566.59 km across and is located at 43.27 S and 253.96°E.

 

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Topographical Map of Icaria Planum

 

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Layers in mantle deposit in Icaria Planum, as seen by HiRISE, under the HiWish program. Mantle was probably formed from snow and dust falling during a different climate.

 

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Crater and one of many nearby channels, as seen by HiRISE under HiWish program. Picture is from Icaria Planum.

At 248°E 43.4°S we come across some strange terrain in the Icaria Planum that is worth noting:

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Strange surface features, as seen by HiRISE under the HiWish program

Near the northern border of the Thaumasia Region from 251°E to 35°S is the Claritas Rupes.

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Striated Highlands Near Claritas Rupes

This observation shows striated highlands that are probably the result of what is termed "mass wasting" when material higher up collapses and flows down slope. This area was also imaged by MOC, but HiRISE resolution (which has a smaller footprint) can show greater detail, enabling us to look for objects such as boulders.  Claritas Rupes extends southward from the western edge of Noctis Labyrinthus and divides the volcanic flows of Deadalia Planum and Solis Planum. This area also has other interesting geological features, such as fractures and a graben, which is a depressed block of land bordered by parallel faults.

 

To the south of Claritas Rupes we come to Claritas Fossae. Note only the western part of these two areas can be considered a part of the Icaria Planum from about 265°E westward extending as far south as about 45°S. 

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Claritas Fossae Graben at 261°E 36.5°S

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Trough in Claritas Fossae at 254°E 38°S.

Just as on Earth, volcanism and tectonics are found together on Mars. Here is an example: the ridges and fractures of Claritas Fossae are affecting or perhaps hosting the volcanic flows of Solis Planum.  Claritas Fossae is a group of troughs in the Phoenicis Lacus and Thaumasia Regions of Mars, located at 31.5° S and 254°E. The structure is 2,050 km long (from north to south) and was named after a classical albedo feature.

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Claritas Fossae as seen by HiRISE. Note the steep scarp which is located at 31.5°S 254°E

Long narrow depressions on Mars are called fossae. This term is derived from Latin; therefore fossa is singular and fossae is plural. Troughs form when the crust is stretched until it breaks. The stretching can be due to the large weight of a nearby volcano. Fossae/pit craters are common near volcanoes in the Tharsis and Elysium regions. A trough often has two breaks with a middle section moving down, leaving steep cliffs along the sides; such a trough is called a graben.

 

To the southwest of the Icaria Planum in the Aonia Terra we come to Porter Crater at 246°E 50.5°S.

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Porter Crater Rim, as seen by MGS. Location is 49.51 degrees south latitude and 246 degrees east longitude

 

Porter Crater: is a large-scale impact crater in the Thaumasia Region on the planet Mars, situated in Aonia Terra at 50.5° south and 246º east. The impact caused a bowl 105 kilometers (65 mi) across. The name was chosen in 1973 by the International Astronomical Union in honor of the US astronomer and explorer, Russell W. Porter (1871-1949).

 

All of the Aonia Terra Region follows the 50°S line across the Thaumasia Region.  I will post a image of Aonia Terra each time we cross the 50°S line since it crosses the entire Region close to that latitude.

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Topographical Map of Aonia Terra at 255.6°E 53.6°S

 

The Aonia Terra Covers an expanse of  over 4,000 kilometers.

 

The next feature of interest we come to is Brashear Crater centered at 241°E 54°S right on the western border of the Thaumasia Region.

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Topographical Map of Brashear Crater

 

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Crater floor covered with sand dunes in the shape of cells, as seen by HiRISE under HiWish program.

Many places on Mars have sand dunes. Some craters in Thaumasia Region show dark blotches in them. High resolution photos show that the dark markings are dark sand dunes. Dark sand dunes probably contain the igneous rock basalt. Brashear Crater, is one such crater with dark dunes.

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Dark Dunes in Brashear Crater

Brashear Crater is 79 kilometers in diameter and is named after Dr. John Alfred Brashear (November 24, 1840 – April 8, 1920) who was an American astronomer and instrument builder.

 

 

The next feature of interest we come to is Ross Crater centered at 253°E 53°S.

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CTX context for gullies in Ross crater.

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Enlargement of part of previous image showing smaller gullies inside larger ones. Water probably flowed in these gullies more than once.

Another theory might be possible since climate changes may be enough to simply allow ice in the ground to melt and thus form the gullies. During a warmer climate, the first few meters of ground could thaw and produce a "debris flow" similar to those on the dry and cold Greenland east coast.  Since the gullies occur on steep slopes only a small decrease of the shear strength of the soil particles is needed to begin the flow. Small amounts of liquid water from melted ground ice could be enough. Calculations show that a third of a mm of runoff can be produced each day for 50 days of each Martian year, even under current conditions.  Ross Crater  is 82.51 km in diameter. It was named after Frank E. Ross, an American astronomer (1874-1966). The crater's name was approved in 1973.

The Climate of Mars

 

Sample of the Weather on Mars

The climate of Mars has been an issue of scientific curiosity for centuries, not least because Mars is the only terrestrial planet whose surface can be directly observed in detail from the Earth with help from a telescope.  Although Mars is smaller at 11% of Earth's mass and 50% farther from the Sun than the Earth, its climate has important similarities, such as the polar ice caps, seasonal changes and the observable presence of weather patterns. It has attracted sustained study from planetologists and climatologists. Although Mars's climate has similarities to Earth's, including seasons and periodic ice ages, there are also important differences such as the absence of liquid water (though frozen water exists) and much lower thermal inertia. Mars' atmosphere has a scale height of approximately 11 km (36,000 ft), 60% greater than that on Earth.   The climate is of considerable relevance to the question of whether life is or was present on the planet.

 

Mars has been studied by Earth-based instruments since as early as the 17th century but it is only since the exploration of Mars began in the mid-1960s that close-range observation has been possible. Flyby and orbital spacecraft have provided data from above, while direct measurements of atmospheric conditions have been provided by a number of landers and rovers. Advanced Earth orbital instruments today continue to provide some useful "big picture" observations of relatively large weather phenomena. This observational work has been complemented by a type of scientific computer simulation called the Mars General Circulation Model.

 

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Mars General Circulation Model

The Mars general circulation model (MGCM) is the result of a research project by NASA to understand the nature of the general circulation of the atmosphere of Mars, how that circulation is driven and how it affects the climate of Mars in the long term. This Mars climate model is a complex 3-dimensional (height, latitude, longitude) model, which represents the processes of atmospheric heating by gases and ground-air heat transfer, as well as large-scale atmospheric motion.  Several different iterations of MGCM have led to an increased understanding of Mars as well as the limits of such models. Models are limited in their ability to represent atmospheric physics that occurs at a smaller scale than their resolution. They also may be based on inaccurate or unrealistic assumptions about how Mars works and certainly suffer from the quality and limited density in time and space of climate data from Mars.

 

Clouds:

Mars' temperature and circulation vary from year to year (as expected for any planet with an atmosphere). Mars lacks oceans, a source of much inter-annual variation. Mars Orbiter Camera data beginning in March 1999 and covering 2.5 Martian years show that Martian weather tends to be more repeatable and hence more predictable than that of Earth. If an event occurs at a particular time of year in one year, the available data (sparse as it is) indicate that it is fairly likely to repeat the next year at nearly the same location give or take a week.  On September 29, 2008, the Phoenix lander took pictures of snow falling from clouds 4.5 km above its landing site near Heimdall crater. The precipitation vaporized before reaching the ground, a phenomenon called virga.  In meteorology, virga is an observable streak or shaft of precipitation that falls from a cloud but evaporates or sublimes before reaching the ground.

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Animation of ice clouds moving above the Phoenix landing site over a period of ten minutes (August 29, 2008).

Animation of ice clouds moving above the Phoenix landing site over a period of ten minutes (August 29, 2008).  Mars' dust storms can kick up fine particles in the atmosphere around which clouds can form. These clouds can form very high up, up to 100 km (62 mi) above the planet. The clouds are very faint and can only be seen reflecting sunlight against the darkness of the night sky. In that respect, they look similar to the mesospheric clouds, also known as noctilucent clouds on Earth, which occur about 80 km (50 mi) above our planet.

 

Temperature:

Differing values have been reported for the average temperature on Mars, with a common value being -55 °C (-67 °F).  Surface temperatures may reach a high of about 20 °C (68 °F) at noon, at the equator, and a low of about -153 °C (-243 °F) at the poles. Actual temperature measurements at the Viking landers' site range from -17.2 °C (1.0 °F) to -107 °C (-161 °F). The warmest soil temperature on the Mars surface estimated by the Viking Orbiter was 27 °C (81 °F). The Spirit rover recorded a maximum daytime air temperatures in the shade of 35 °C (95 °F), and regularly recorded temperatures well above 0 °C (32 °F), except in winter.

 

Wind:

The surface of Mars has a very low thermal inertia, which means it heats quickly when the sun shines on it. Typical daily temperature swings, away from the polar regions, are around 100 K. On Earth, winds often develop in areas where thermal inertia changes suddenly, such as from sea to land. There are no seas on Mars, but there are areas where the thermal inertia of the soil changes, leading to morning and evening winds akin to the sea breezes on Earth.  At low latitudes the Hadley circulation dominates, and is essentially the same as the process which on Earth generates the trade winds. At higher latitudes a series of high and low pressure areas, called baroclinic pressure waves, dominate the weather. Mars is dryer and colder than Earth, and in consequence dust raised by these winds tends to remain in the atmosphere longer than on Earth as there is no precipitation to wash it out (excepting CO2 snowfall).

 

Effect of Dust Storms:

When the Mariner 9 probe arrived at Mars in 1971, the world expected to see crisp new pictures of surface detail. Instead they saw a near planet-wide dust storm with only the giant volcano Olympus Mons showing above the haze. The storm lasted for a month, an occurrence scientists have since learned is quite common on Mars.  As observed by the Viking spacecraft from the surface, "during a global dust storm the diurnal temperature range narrowed sharply, from fifty degrees to only about ten degrees, and the wind speeds picked up considerably---indeed, within only an hour of the storm's arrival they had increased to 17 m/s (38 mph), with gusts up to 26 m/s (58 mph). Nevertheless, no actual transport of material was observed at either site, only a gradual brightening and loss of contrast of the surface material as dust settled onto it.  On June 26, 2001, the Hubble Space Telescope spotted a dust storm brewing in Hellas Basin on Mars (below). A day later the storm "exploded" and became a global event. Orbital measurements showed that this dust storm reduced the average temperature of the surface and raised the temperature of the atmosphere of Mars by 30 °C. The low density of the Martian atmosphere means that winds of 18 to 22 m/s (40 to 49 mph) are needed to lift dust from the surface, but since Mars is so dry, the dust can stay in the atmosphere far longer than on Earth, where it is soon washed out by rain.

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2001 Hellas Basin dust storm

 

Seasons:

Mars has an axial tilt of 25.2°. This means that there are seasons on Mars, just as on Earth. The eccentricity of Mars' orbit is 0.1, much greater than the Earth's present orbital eccentricity of about 0.02. The large eccentricity causes the isolation on Mars to vary as the planet orbits the Sun (the Martian year lasts 687 days, roughly 2 Earth years). As on Earth, Mars' obliquity dominates the seasons but, because of the large eccentricity, winters in the southern hemisphere are long and cold while those in the North are short and warm.  It is now widely believed that ice accumulated when Mars' orbital tilt was very different from what it is now (the axis the planet spins on has considerable "wobble," meaning its angle changes over time).  A few million years ago, the tilt of the axis of Mars was 45 degrees instead of its present 25 degrees. Its tilt, also called obliquity, varies greatly because its two tiny moons cannot stabilize it like our moon.  Many features on Mars, especially in the Ismenius Lacus Region, are believed to contain large amounts of ice. The most popular model for the origin of the ice is climate change from large changes in the tilt of the planet's rotational axis. At times the tilt has even been greater than 80 degrees.   Large changes in the tilt explains many ice-rich features on Mars

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In spring, sublimation of ice causes sand from below the ice layer to form fan-shaped deposits on top of the seasonal ice.

Season                                          Sols (on Mars)        Days (on Earth)

Northern Spring, Southern Autumn:      193.30                                92.764

 

Northern Summer, Southern Winter:     178.64                                93.647

 

Northern Autumn, Southern Spring:       142.70                                89.836

 

Northern Winter, Southern Summer:     153.95                                88.997

 

Climate zones:

Terrestrial Climate zones first have been defined by Wladimir Köppen based on the distribution of vegetation groups. Climate classification is furthermore based on temperature, rainfall, and subdivided based upon differences in the seasonal distribution of temperature and precipitation; and a separate group exists for extra zonal climates like in high altitudes. Mars has neither vegetation nor rainfall, so any climate classification could be only based upon temperature; a further refinement of the system may be based on dust distribution, water vapor content, occurrence of snow. Solar  Climate Zones  can also be easily defined for Mars.

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Mars Global Climate Zones, based on temperature, modified by topography, albedo, actual solar radiation.

Summary:

Mars Global Climate Zones, based on temperature, modified by topography, albedo, actual solar radiation. A=Glacial (permanent ice cap); B=Polar (covered by frost during the winter which sublimates during the summer); C=North (mild) Transitional (Ca) and C South (extreme) Transitional (Cb); D= Tropical; E= Low albedo tropical; F= Subpolar Lowland (Basins); G=Tropical Lowland (Chasmata); H=Subtropical Highland (Mountain).

 

 

Northeast of Ross crater is Coblentz Crater centered at 270°E 55°S.

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Coblentz Crater

Coblentz Crater is 112 kilometers in diameter and was named after William Weber Coblentz (November 20, 1873 – September 15, 1962) who was an American physicist notable for his contributions to infrared radiometry and spectroscopy.

 

Next we cross another part of the Aonia Terra Area around 50°S.

 

Aonia Terra Sample from about 270-290°E

These dunes in Aonia Terra are being monitored for changes such as gullies, which form over the winter from the action of carbon dioxide frost.  The season in which these images were acquired in late fall in the Southern hemisphere. Frost is just starting to accumulate here, and is concentrated on pole-facing slopes and in the troughs between the meter-scale ripples.  The colors have been enhanced in the sub-image.  Throughout the latter part of this video in Aonia Terra, it is possible to make out regular polygonal shaped patterns. Here on Earth, wherever ice-rich permafrost occurs (soil which stays frozen throughout the year), the ground may crack and form similar patterns to those we see on Mars.  Despite remaining below freezing, changes in seasons and ground temperature cause significant thermal-contraction stress, enough so that the terrain fractures change into a honeycomb network of subsurface cracks.  Criss-crossed dark paths wind throughout this region. Dust devils, turbulent whirlwinds fueled by rising ground-warmed atmosphere, track across the surface, stripping the ground of bright surface dust as they go. Comparable to miniature tornadoes, they efficiently transport surface materials on Mars. Left in their passing is the darker coarse-grained soil underneath.

 

To the northwest of Coblentz Crater is the Thaumasia Fossae located between 257-265°E and between 45-50°S. 

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Thaumasia Fossae Area at 261.8°E 47.3°S

The next area of interest we come to is the Warrego Valles located at about 296°E and 42°S.

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Channels near Warrego Valles, as seen by THEMIS. These branched channels are strong evidence for flowing water on Mars, perhaps during a much warmer period.

Mariner 9 and Viking Orbiter images, showed a network of branching valleys in the Thaumasia Region called Warrego Valles. These networks are evidence that Mars may have once been warmer, wetter, and perhaps had precipitation in the form of rain or snow. A study with the Mars Orbiter Laser Altimeter, Thermal Emission Imaging System (THEMIS) and the Mars Orbiter Camera (MOC) support the idea that Warrego Valles was formed from precipitation and run off. At first glance they resemble river valleys on our Earth. But sharper images from more advanced cameras reveal that the valleys are not continuous. They are very old and may have suffered from the effects of erosion. The picture above shows some of these branching valleys

Warrego Valles

To the north of Warrego Valles on the border we com to Solis Planum which stretches from 265-280°E.   Solis Planum is a high-elevation volcanic plain located south of Valles Marineris. This particular location is south of the southeastern tip of Noctis Labyrinthus. Solis Planum covers and area of 1700 kilometers.

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Wrinkle Ridge in Solis Planum at 276°E 26°S

 

This observation shows a wrinkle ridge in the Solis Planum, a region of Mars that is a high-elevation volcanic plain located south of the Valles Marineris canyon system and east of the Tharsis volcanic complex. In the Solis Planum, wrinkle ridges are typically spaced apart roughly 40 kilometers (25 miles).  Wrinkle ridges are linear to arcuate positive relief features and are often characterized by a broad arch topped with a crenulated ridge. These features have been identified on many bodies such as the Moon, Mercury, and Venus. On Mars, they are many tens-to- hundreds of kilometers long, tens of kilometers wide, and have a relief of a few hundred meters. Wrinkle ridges are most commonly believed to form from horizontal compression or shortening of the crust due to faulting and are often found in volcanic plains.  Wrinkle ridges commonly have asymmetrical cross sectional profiles and an offset in elevation on either side of the ridge. The ridge in this image appears to have a steeper southeast facing slope and a more gentle northwest facing slope. Some layering is also apparent in the ridge. Large dunes border the ridge to the north.  The reddish colors visible in the color image most likely indicate the presence of dust (or indurated dust).

The Solis Planum Area

To the east of Solis Planum is Voeykov Crater centered at  284°E 31.5°S.

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Voeykov Crater in the Infrared 

Voeykov Crater is 76 kilometers in diameter and is named after the Russian astronomer A.I. Voeykov.

 

Going to the southwest we come to the Coracis Fossae.  The Coracis Fossae covers the southeast region of the uplift south of the Solis Planum.  Roughly from 284°E to about 275°E and going as far south as 42°S.  It covers a large area and has a diameter of 749 kilometers.  It is named after an albedo feature.

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Location of Coracis Fossae

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Inclined view of Coracis Fossae

Coming down from the uplift that is Coracis Fossae we head to south to Slipher Crater which is centered at 275.5°E 47°S.

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Slipher Crater

Slipher Crater is 127 kilometers in diameter and is named after Vesto Melvin Slipher (November 11, 1875 – November 8, 1969) who was an American astronomer.

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Channels in Aonia Terra at 282°E 41°S.

Next we come to a Lowell Crater centered at 279°E 52.5°S.

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Lowell Crater

Lowell crater is somewhat special in that it has a ring on the floor which gives it a sort of bull's eye appearance. It should be special because it was named after Percival Lowell who built the Lowell Observatory in Flagstaff Arizona in 1894. He used the observatory to discover over 500 canals on Mars. When pictures were received from spacecraft, the canals were found to be illusions. However, Lowell promoted the idea that they were constructed by an intelligent race. Much of the later interest in Mars exploration resulted from the efforts of Percival Lowell.  Lowell Crater is 203 kilometers in diameter.  It is considered to be a part of Aonia Terra.

 

Just to the southwest of there we come to a mountain called Aonia Mons located at 272.5°E 53.5°S.

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Location of Aonia Mons

South of there we come to the Aonia Planum Area:

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Aonia Planum Area

In the center of which is Aonis Tholus  which is a small dome shaped mountain located at 280°E 59°S.

 

To the southeast of this Aonia Planum is a escarpment called Argyre Rupes starting at 294°E 64.5°S and going in a northwesterly direction to about 291°E 60°S.

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Topographical Map of Argyre Rupes

Going almost directly north and east of Lowell Crater we come to Douglass Crater centered at 289.5°E 52°S.

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Central Structure of Douglass Crater

Douglass Crater is 94 kilometers in diameter and is named after A. E. (Andrew Ellicott) Douglass (July 5, 1867, Windsor, Vermont – March 20, 1962, Tucson, Arizona) was an American astronomer.  Douglass crater is part of Aonia Terra.

 

Continuing north we come to the next important feature we come to is  Babakin Crater located at 289°E 37°S.

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Bedrock in Babakin Crater

HiRISE acquires many images of bedrock exposures inside impact craters, because deep bedrock may be exposed in the central uplift, or new deposits may form on the floor. The sub image shows an enhanced-color section of the crater floor of one crater. There are layers of rock with different colors (from different minerals) exposed in places where the dark reddish wind-blown drifts have been removed.  Babakin Crater is 78 kilometers in diameter and is named after Georgy Nikolayevich Babakin ( November 13, 1914 – August 3, 1971) who was a Soviet engineer working in the space program.

 

The final area  of importance is the Bosphorus Planum area in the northeast corner of the Thaumasia Region.

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Textured Mesa Southeast of Bosporus Planum

Also imaged by MRO's Context Camera, this observation shows one of two odd, rounded mesas with a knobby/pitted texture.  This mesa may be the last remnants of a formerly more extensive geologic unit. Given the particular pitted texture, this formation could be ice-rich.  High resolution images can greatly help to characterize the surface texture and allow us to compare other mid-latitude-type landforms, which may have some connection with ice and sublimation degradation processes.

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Many Fantastically Colorful Gullies in a Fresh Impact Crater in the Bosporus Planum

 

This image covers a "fresh-looking" impact crater with a diameter of about 2 kilometers (1.2 miles). There are gullies all around the steep inner slopes of this crater (you can even see them in the shadow by enhancing the brightness of this region), at 35 degrees South latitude right in the middle of the Bosporus Planum. Many craters at this latitude in the southern hemisphere only have gullies on the south-facing slopes, which are shadowed in the wintertime. But this is an especially pristine crater so the slopes may be particularly steep and unstable.  The enhanced color sub image shows that gullies and their deposits have many different colors. This is due to diverse rock types exposed by the crater and the fact that the gullies have been recently active, so colors have not been homogenized by overlying regolith (soil) or windblown deposits. HiRISE will monitor this site in the future to see if the gullies are currently active.  How long ago did this crater form? It appears nearly pristine, preserving meter-scale morphologies in the ejecta, and there are almost no superimposed (younger) impact craters, so it is probably less than a million years old. That means the crater formed in the most recent 0.02 percent of Mars' existence. The ejecta includes a "herringbone" texture with V-shaped features pointing to the source crater. The Bosporus Planum covers and area of 729 kilometers in diameter and it is named after an albedo feature.

Thursday, March 20, 2014

Small Pale Red Planet Issue 4 Phase 1

 

The Phaethontis Region

MC-24


The Phaethontis Region lies between 30° and 65 ° south latitude and 120° and 180 ° west longitude on Mars. This latitude range is where numerous gullies have been discovered. An old feature in this area, called Terra Sirenum lies in this Region; the Mars Reconnaissance Orbiter discovered iron/magnesium Smectite there. Part of this Region contains what is called the Electris deposits, a deposit that is 100–200 meters thick. It is light-toned and appears to be weak because of few boulders.   There are problems with acquiring photos and videos of many places on Mars.  Some areas have been looked at more than others especially through such programs as the HiWish Program.  NASA probably has images of almost all the planet through the Mars Odyssey and MRO satellites.  The three Rovers only have a small amount of information because their areas of exploration have been very limited not more than 25 miles at the most (an that by Opportunity) hopefully Curiosity will break all the records since it seems to be of better construction than anything thus far.  The Mars Express by ESA has also furnished many photos and videos  Then we have DTMs and not too many of those have been made along with DTM animations and even fewer of those have been made so what is available is limited to me.  But I will do the best I can for you.

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Topographical Map of the Phaethontis Region

Among a group of large craters is Mariner Crater, first observed by the Mariner IV spacecraft in the summer of 1965. It was named after that spacecraft. A low area in Terra Sirenum is believed to have once held a lake that eventually drained through Ma'adim Vallis. Russia's Mars 3 probe landed in the Phaethontis quadrangle at 44.9° S and 160.1° W in December 1971. It landed at a speed of 75 km per hour, but survived to radio back 20 seconds of signal, then it went dead. Its message just appeared as a blank screen.

 

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Image of the Phaethontis Region


We begin our Survey of the Phaethontis Region from the northeast corner.  We first come to the Atlantis Chaos at 34°S 183°E.

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Possible MSL Rover Landing Site Atlantis Chaos

The Atlantis Chaos is a region of disrupted terrain in the Phaethontis Region of Mars.

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You can see the mantle covering and possible gullies. The two images are different parts of the original image. They have different scales

This region is 162 kilometers (101 mi) across, and was named after an albedo feature.

 

Just to the northeast of Atlantis Crater is Magelhaens Crater centered at 185.5°E 32.4°S.

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Megelhaens Crater

This is an image of the central pit of an impact crater in the ancient highlands. The central uplifts of large impact craters often collapse to form pits on Mars, but they are still structural uplifts and often expose deep bedrock with diverse rock types which have a variety of colors.  In this enhanced color sub-image, we see colorful streaks, where the bedrock is eroding, moving downhill a bit, then getting swept by the wind.   Magelhaens is an impact crater in the southern highlands of Mars. It is 105 km in diameter and was named for Ferdinand Magellan, the 16th century Portuguese explorer.  Magelhaens is located southwest of the volcanic region of Tharsis. It is surrounded by rocky peaks of unknown origin. These forms may be the result of tectonic movements in the Tharsis region, or of meteorite impact.


The Gorgonum Chaos is a set of canyons in the Phaethontis Region of Mars. It is located at 37.5° south latitude and 189° east longitude. Its name comes from an albedo feature.  The Phaethontis Region is the location of many gullies that may be due to recent flowing water. Some are found in the Gorgonum Chaos. Gullies occur on steep slopes, especially craters. Gullies are believed to be relatively young because they have few, if any craters, and they lie on top of sand dunes which are young. Usually, each gully has an alcove, channel, and apron. Although many ideas have been put forward to explain them, the most popular involve liquid water either coming from an aquifer or left over from old glaciers.

The Gorgonum Chaos

Sirenum Fossae is a trough that starts at 220°E 25°S in the Memnonia Region and  enters into the Phaethontis Region at about 211°E 30°S.   Sirenum Fossae is 2,735 km long and was named after a classical albedo feature name. It cuts across the Phaethontis Region on about a 30° angle going to the southwest and exiting the Phaethontis Region at 180°E 39°S. Troughs on Mars like this one are called Fossae. Sirenum Fossae is believed to have formed by movement along a pair of faults causing a center section to drop down. This kind of feature is called a graben.

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Sirenum Fossae in the Northeast Phaethontis Region

 

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Sirenum Fossae

The Mars Express High Resolution Stereo Camera has imaged craters both young and old in this view of the Southern Highlands of Mars.  This Part of the Sirenum Fossae region in the Southern Highlands, the area in this image is centered at about 28°S / 185°E. The image captures an area to the north of the Magelhaens Crater.  But it also extends south of the Crater as well. It extends some 230 km by 127 km and covers about 29 450 sq. km, roughly the size of Belgium. The image resolution is approximately 29 meters per pixel.

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Perspective view of Sirenum Fosse’s central plateau

 

Sirenum Fossae is a system of grabens, formed by stresses placed on the crust during the uprising of the Tharsis region. A graben is visible as two sets of parallel lines running from top to bottom to the left of center. The Southern Highlands are believed to be older than the Northern Lowlands, based on the larger number of impact craters seen to cover the region. Craters of 50 km in diameter are common in this area and have usually suffered from erosion, indicating they were formed during ancient times.

 

Just east of the Gorgonum Chaos is Triolet Crater amid the graben of the Sirenum Fossae.

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Triolet Crater

Triolet Crater is a small crater 11.66 kilometers in diameter and is named after a Mauritius place name.

 

Going farther south we come to the large Copernicus Crater centered at  191°E 49°S.

Copernicus Crater

Copernicus Crater is 294 kilometers in diameter. It was named after Nicolaus Copernicus (Polish; 19 February 1473 – 24 May 1543) who was a Renaissance mathematician and astronomer who formulated a heliocentric model of the universe which placed the Sun, rather than the Earth, at the center of the solar system.

 

To the east of Copernicus Crater is Very Crater centered at 182.5°E  49°S.

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Very Crater

Very Crater is 114 kilometers in diameter.  The crater is named after Frank Washington Very (1852 – November 23, 1927) who was a U.S. astronomer.

To the southeast of Very Crater is Liu Hsin Crater centered at about 187°E 53.5°S.

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Liu Hsin Crater Ejecta and Surrounding Terrain


Possible Olivine-Rich Rim of Liu Hsin Crater with Mantle relating to Sedimentary/Layering Processes.  Liu Hsin Crater is 137 kilometers in diameter.  This crater was named after  Liu Xin (ca. 50 BC – AD 23), later changed name to Liu Xiu , courtesy name Zijun , was a Chinese astronomer, historian, and editor during the Western Han Dynasty (206 BC-AD 9) and Xin Dynasty (AD 9–23).

 

Going to the south at 209°E 61.5 S we come to Keeler Crater and Trumpler Crater-

one superimposed on top of the other.

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Keeler and Trumpler Crater (the latter is the bottom crater in this image)

Trumpler Crater is in the far southern part of the Martian highlands.  This HiRISE image shows a frozen terrain typical at these latitudes. The surface is mantled by a deposit that is postulated to be largely a mix of dust and ice. However, many of the higher hills have had this mantle removed and the older rocks are exposed. In some parts of Mars there is good evidence for ice having flowed from higher to lower ground, but there is no such evidence here. Perhaps the mantling deposit never formed on the tops of these hills or it was preferentially removed from these places.  In the flatter locations, the mantling deposit is completely covered by small cracks that form a polygonal network. These are clearest in the southern part of the image, where the sun is almost parallel to the surface, producing dramatic shadows. Such polygons are a common feature in permafrost.

 

Going directly north there is Wright crater centered at 209.5° E 58.5° S.

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Wright Crater (large crater in center of image)

 

Wright Crater is 115 kilometers in diameter and is named after William Hammond Wright (November 4, 1871 – May 16, 1959) who was an American astronomer. He was director of the Lick Observatory from 1935 until 1942.

 

To the northwest of the latter crater is Kuiper Crater at 202.5°E 57.5°S.

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Kuiper Crater (in center)

Kuiper Crater is 87 kilometers in diameter and was named after  Gerard Peter Kuiper; born Gerrit Pieter Kuiper; December 7, 1905 – December 23, 1973) was a Netherlands-born American astronomer after whom the Kuiper belt was named.

 

Almost directly north of Kuiper Crater is Nordenskiöld Crater  centered at  202.5°E 53°S.

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Nordenskiöld Crater

Nordenskiöld Crater is 89 kilometers in diameter and is named after Friherr Nils Adolf Erik Nordenskiöld (18 November 1832, Helsinki, Finland – 12 August 1901, Dalbyö, Södermanland, Sweden) was a Finnish baron, botanist, geologist, mineralogist and arctic explorer of Finland-Swedish origin.

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Tader Valles

To the northeast of this crater is the Tader Valles a set of small channels in the Phaethontis Region found at 49.1° south latitude and 208° east longitude.  Tader Valles, an ancient name for the present day Segura River in Spain, is a set of small channels at mid-southern latitudes that is filled by smooth material with rounded margins. It is possible that this material is snow covered by a mantle of dust or dirt.  Tader Valles is 200 kilometers in length.

 

To the north of Tader Valles is Li Fan Crater centered at 207°E 46.5°S.

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Li Fan Crater

Li Fan Crater is 104.8 kilometers in diameter and is named after  Li Fan who was a Chinese astronomer during the Han Dynasty (202 BC-220 AD).

 

Just to the northwest of Li Fan crater is Ptolemaeus Crater centered at 202.5°E 46.5°S.

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Ptolemaeus Crater

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Mars-3 Lander Hardware Found?

This set of images shows what might be hardware from the Soviet Union's 1971 Mars 3 lander, seen in a pair of images from the High Resolution Imaging Science Experiment (HiRISE) camera on NASA's Mars Reconnaissance Orbiter.  The possible Mars 3 lander hardware was found by an Internet group of Russian citizen enthusiasts who follow news about Mars and NASA's Curiosity rover.  In 1971, the former Soviet Union launched the Mars 2 and Mars 3 missions to Mars. Each consisted of an orbiter plus a lander. Both orbiter missions succeeded, although the surface of Mars was obscured by a planet-encircling dust storm. The Mars 2 lander crashed. Mars 3 became the first successful soft landing on the Red Planet, but stopped transmitting after just 20 seconds for unknown reasons.  The predicted landing site was at latitude 45 degrees south, longitude 202 degrees east, in the Ptolemaeus Crater. HiRISE acquired a large image at this location in November 2007. This image contains 1.8 billion pixels of data, so about 2,500 typical computer screens would be needed to view the entire image at full resolution. Promising candidates for the hardware from Mars 3 were found on December 31, 2012.  Vitali Egorov from St. Petersburg, Russia, heads the largest Russian Internet community about Curiosity. His subscribers did the preliminary search for Mars 3 via crowd-sourcing. Egorov modeled what Mars 3 hardware pieces should look like in a HiRISE image, and the group carefully searched the many small features in this large image, finding what appears to be viable candidates in the southern part of the scene. Each candidate has a size and shape consistent with the expected hardware, and they are arranged on the surface as expected from the entry, descent and landing sequence.

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Mars 3 Lander model at the Memorial Museum of Cosmonautics in Russia

Ptolemaeus Crater is a crater on Mars found in the Phaethontis Region. It is 165.18 km in diameter and was named after Claudius Ptolemaeus, a Greco-Egyptian astronomer (c. AD 90-160). 

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Hipparchus Crater

Hipparchus Crater is northeast of Ptolemaeus Crater centered at 208.5°E 45°S. Hipparchus Crater is 93 kilometers in diameter and is named after Hipparchus of Nicaea; c. 190 – c. 120 BC), who was a Greek astronomer, geographer, and mathematician of the Hellenistic period.

 

Next we come to Newton Crater centered at 202°E 41°S.  Newton Crater is a large crater on Mars, with a diameter close to 300 km. It is located south of the planet's equator in the heavily cratered highlands of Terra Sirenum. The impact that formed Newton likely occurred more than 3 billion years ago. The crater contains smaller craters within its basin and is particularly notable for gully formations that are presumed to be indicative of past liquid water flows. Many small channels exist in this area; they are further evidence of liquid water.

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Gullies near Newton Crater, as seen by HiRISE.

 

The Phaethontis Region is the location of many gullies that may be due to recent flowing water. Some are found in Newton Crater.  Gullies occur on steep slopes, especially that of craters. Gullies are believed to be relatively young because they have few, if any craters, and they lie on top of sand dunes which are young. Usually, each gully has an alcove, channel, and apron. Although many ideas have been put forward to explain them, the most popular involve liquid water either coming from an aquifer or left over from old glaciers.  There is disagreement in the scientific community as to whether or not the recent gully streaks were formed by liquid water (some suspect dry ice CO2). Some suggest the flows were merely dry sand flows. Others suggest it may be liquid brine near the surface, but the exact source of the water and the mechanism behind its motion will not understood until we send someone there to find out.  Analysis of Martian sandstones, using data obtained from orbital spectrometry, suggests that the waters that previously existed on the surface of Mars would have had too high a salinity to support most Earth-like life. Tosca et al. found that the Martian water in the locations they studied all had water activity, aw ≤ 0.78 to 0.86—a level fatal to most Terrestrial life.


 

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Gullies and Craters on the Floor of Newton Basin  HiRISE DTM

Microscopic life known as Haloarchaea, however, are able to live in hyper-saline solutions, up to the saturation point. In June 2000, possible evidence for current liquid water flowing at the surface of Mars was discovered in the form of flood-like gullies. Additional similar images were published in 2006, taken by the Mars Global Surveyor, that suggested that water occasionally flows on the surface of Mars. The images did not actually show flowing water. Rather, they showed changes in steep crater walls and sediment deposits, providing the strongest evidence yet that water coursed through them as recently as several years ago.

Newton Crater Activity

The region nearby is dominated by heavily cratered highlands and low-lying areas forming relatively smooth plains.  The Electris deposits is 100–200 m thick deposit that is light-toned and appears to be weak because few boulders are seen associated with it. The deposit mostly covers ground from 30° S to 45° S and from 160° E to 200° E. So, some of it lies in the Phaethontis Region and the rest in Eridania Region. Recent work with HiRISE images lead scientists to believe that the deposit is an accumulation of loess that initially were produced from volcanic materials in Tharsis or other volcanic centers.  (Loess is an Aeolian sediment formed by the accumulation of wind-blown silt, typically in the 20–50 micrometer size range, twenty percent or less clay and the balance equal parts sand and silt that are loosely cemented by calcium carbonate).  Using a global climate model, a group of researchers headed by Laura Kerber found that the Electris deposits could have easily been formed from ash from the volcanoes Apollinaris Mons, Arsia Mons, and possibly Pavonis Mons. Its named after one of the Classical albedo features on Mars.

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Electris Deposit, as seen by HiRISE. Electris deposit is light-toned and smooth in the image in contrast to rough materials below-location is Phaethontis Region.

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Deposits in Electris

This observation reveals a portion of a long outcrop of a deposit in the Electris region of Mars. The Electris deposits occur over a range of landforms and relief and the process(es) responsible for their emplacement remain speculative.   Close examination of the outcrops reveal layering that in some places appear to include meter-scale blocks.

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Unconformable Deposits in Electris Region

Comparison with other HiRISE images of the deposit will enable more detailed mapping of its extent and nature and should provide new insight into the origin of these enigmatic materials.

 

Magnetic Stripes and Plate Tectonics:  The Mars Global Surveyor (MGS) discovered magnetic stripes in the crust of Mars, especially in the Phaethontis and Eridania Regions (Terra Cimmeria and Terra Sirenum).The magnetometer on MGS discovered 100 km wide stripes of magnetized crust running roughly parallel for up to 2000 km. These stripes alternate in polarity with the north magnetic pole of one pointing up from the surface and the north magnetic pole of the next pointing down. When similar stripes were discovered on Earth in the 1960s, they were taken as evidence of plate tectonics. Researchers believe these magnetic stripes on Mars are evidence for an short, early period of plate tectonic activity. When the rocks became solid they retained the magnetism that existed at the time. A magnetic field of a planet is believed to be caused by fluid motions under the surface. However, there are some differences, between the magnetic stripes on Earth and those on Mars. The Martian stripes are wider, much more strongly magnetized, and do not appear to spread out from a middle crustal spreading zone. Because the area containing the magnetic stripes is about 4 billion years old, it is believed that the global magnetic field probably lasted for only the first few hundred million years of Mars' life, when the temperature of the molten iron in the planet's core might have been high enough to mix it into a magnetic dynamo. There are no magnetic fields near large impact basins like Hellas. The shock of the impact may have erased the remnant magnetization in the rock. So, magnetism produced by early fluid motion in the core would not have existed after the impacts.  When molten rock containing magnetic material, such as hematite (Fe2O3), cools and solidifies in the presence of a magnetic field, it becomes magnetized and takes on the polarity of the background field. This magnetism is lost only if the rock is subsequently heated above a particular temperature (the Curie point which is 770°C for iron). The magnetism left in rocks is a record of the magnetic field when the rock solidified.

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This image is a map of Martian magnetic fields in the southern highlands near the Terra Cimmeria and Terra Sirenum regions, centered around 180 degrees longitude from the equator to the pole. It is where magnetic stripes possibly resulting from crustal movement are most prominent. The bands are oriented approximately east - west and are about 100 miles wide and 600 miles long, although the longest band stretches more than 1200 miles. The false blue and red colors represent invisible magnetic fields in the Martian crust that point in opposite directions. The magnetic fields appear to be organized in bands, with adjacent bands pointing in opposite directions, giving these stripes a striking similarity to patterns seen in the Earth's crust at the mid-oceanic ridges. The bands of magnetized crust apparently formed in the distant past when Mars had an active dynamo, or hot core of molten metal, which generated a global magnetic field. Mars was geologically active, with molten rock rising from below cooling at the surface and forming new crust. As the new crust solidified, the magnetic field that permeated the rock was "frozen" in the crust. Periodically, conditions in the dynamo changed and the global magnetic field reversed direction. The oppositely directed magnetic field was then frozen into newer crust.  Like a Martian tape recorder, the crust has preserved a fossil record of the magnetic field directions that prevailed at different times in the ancient past. When the planet's hot core cooled, the dynamo ceased and the global magnetic field of Mars vanished. However, a record of the magnetic field was preserved in the crust and detected by the Global Surveyor instrument. The mission's map of Martian magnetic regions may help solve another mystery -- the origin of a striking difference in appearance between the smooth, sparsely cratered northern lowlands of Mars and the heavily cratered southern highlands. The map reveals that the northern regions are largely free of magnetism (although they might be buried by an ancient sea floor), indicating the northern crust formed after the dynamo died. The map also identifies an area in the southern highlands as the oldest surviving unmodified crust on Mars. This area on Mars is where the magnetic stripes are most prominent. The bands are oriented approximately east-to-west and are about 100 miles wide and 600 miles long, although the longest band stretches more than 1,200 miles.

To the northwest of Newton Crater we cross the Sirenum Fossae and come to Mariner Crater centered at 196°E 35°S.

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Mariner Crater and the Sirenum Fossae

The crack that appears in the upper image is almost always referred to as a "ridge" -- as that was how it was described at the time the image was first released. The crack is part of the Sirenum Fossae ("fossae" means "fractures" or "ditches" not ridges.) The crack also appears in the lower image (just barely visible from the lower right corner rising at a 60+ degree angle toward the upper center) .  Mariner Crater is a crater on Mars with a diameter of 170 km. it is located in the Phaethontis Region. It was named for Mariner IV spacecraft. In fact it is probably the best image that was taken with the Mariner IV spacecraft.

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Crater wall inside Mariner Crater, as seen by HiRISE.

Mariner 4 probe performed the first successful flyby of the planet Mars, returning the first pictures of the Martian surface in 1965. The photographs showed an arid Mars without rivers, oceans, or any signs of life. This is probably the best picture that our first spacecraft to fly by Mars took. Image located in Phaethontis Region:

 

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Early Image of Mariner Crater

Further, it revealed that the surface (at least the parts that it photographed) was covered in craters, indicating a possible lack of plate tectonics and weathering. The probe also found that Mars has no global magnetic field that would protect the planet from potentially life-threatening cosmic rays. The probe was able to calculate the atmospheric pressure on the planet to be about 0.6 kPa (compared to Earth's 101.3 kPa), meaning that liquid water could not exist on the planet's surface. After Mariner 4, the search for life on Mars changed to a search for bacteria-like living organisms rather than for multicellular organisms, as the environment was clearly too harsh for these.  But the knowledge we possess today tells us larger life could exist on the planet 3 meters (9 feet+) below the surface where it is possible that the harmful radiation bombarding the planet’s surface would not kill them.

 

Cross Crater located on the northern border of the Phaethontis Region is located at 202.5°E 30°S.

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A Deposit on Mars Layered alunite-kaolinite deposit near Cross Crater on Mars

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Stratigraphy of Potential Hydrothermal System in Cross Crater

Cross Crater is 67. 5 kilometers in diameter and is named after the astronomer Charles Arthur Cross.

 

Terra Sirenum: is a large region in the southern hemisphere of the planet Mars. It is centered at   39.7°S 150°W and covers 3900 km at its broadest extent. It covers latitudes 10 to 70 South and longitudes 110 to 180 W. is an upland area notable for massive cratering including the large Newton Crater. Terra Sirenum is in the Phaethontis Region of Mars. A low area in Terra Sirenum is believed to have once held a lake that eventually drained through Ma'adim Vallis:

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Terra Sirenum Possible Chloride Deposits (salt)

Evidence of deposits of chloride based minerals in Terra Sirenum was discovered by the 2001 Mars Odyssey orbiter's Thermal Emission Imaging System in March 2008. The deposits are approximately 3.5 to 3.9 billion years old. This suggests that near-surface water was widespread in early Martian history, which has implications for the possible existence of Martian life. Besides finding chlorides, MRO discovered iron/magnesium Smectites which are formed from long exposure in water.  Based on chloride deposits and hydrated phyllosilicates, Alfonso Davila and others believe there is an ancient lakebed in Terra Sirenum that had an area of 30,000 km2 and was 200 meters deep.

 

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Chloride Salt Deposits within a Channel in Terra Sirenum  HiRISE DTM  205.4°E 33.4°S

 

The Terra Sirenum Area

Going into the central area of the Phaethontis Region we come to Nansen Crater centered at  219.5°E 50°S.

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Nansen Crater

Nansen Crater is 81 kilometers in diameter and is named after Fridtjof Nansen; 10 October 1861 – 13 May 1930) who was a Norwegian explorer, scientist, diplomat, humanitarian and Nobel Peace Prize laureate.

 

Going southwest from there we come to Millman Crater centered 210.5°E 54°S.

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Olivine-Rich Sand Dunes in Millman Crater

Millman Crater is 75 kilometers in diameter and is named after Peter Mackenzie Millman (August 10, 1906 – December 11, 1990) who was a Canadian astronomer.

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The Icaria Fossae (note the dust devil tracks in this image)

In the east central area in the Phaethontis Region is the Icaria Fossae.  It is a trough with its location centered at 46.4° south latitude and 230° east longitude. It is 280 km long and was named after an albedo feature at 44S, 130W.

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Lava Oozing into Pickering Crater

This image captures a fairly rare situation. In general, as lava flows along, it fills in low points and holes it encounters in its path and flows around high points such as hills and ridges. In this image there are two lava flows interacting with an impact crater.  Although an impact crater approximately 3 kilometers (1.8 miles) wide such as this is a deep hole in the ground (likely a couple hundred meters or several hundred feet deep), it is surrounded by a rim crest that is actually higher than the surrounding terrain, lifted up during the powerful impact that formed the crater originally. On the south side of the crater, a smooth-surfaced lava flow (with some knobs in the southwest) has come in contact with the exterior of the crater rim, burying any sign of ejecta from the crater and covering most of the rim, almost up to the rim crest.

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Pickering Crater Wide Angle Shot (right)

However, because the height of the crater rim was slightly greater than the thickness of the lava flow, the crater rim acted like a wall and prevented the deep crater from being overrun and filled with the lava. Later, however, a different, younger, heavily ridged lava flow approached the crater from the north - the thickness of this ridged lava flow is visible along its flow front in the eastern part of the image. Unlike the earlier flow, the ridged flow overtopped the crater's northeast rim, and a single lobe of lava is descending to the floor of the crater. If the rim had been any lower, or if the lava had advanced any further, the crater would have been filled and buried and we would not be lucky enough to see this snapshot of the dramatic interaction of lava with this crater.  Pickering Crater is a crater in the northern part of the Phaethontis Region on Mars, located at 33.1° south latitude and 227.5 ° east longitude. It is 115 kilometers (71 mi) in diameter and was named after several people: Edward Charles, American astronomer (1846–1919); William Henry, American astronomer (1858–1938); and Sir William Hayward, New Zealand-American engineer (1910–2004).