 |
 (to left, from SEDS, http://www.seds.org/nineplanets/nineplanets/mars.html above, Mangala, the planet Mars, depicted as a red-skinned horseman on a white ram. from The Black Peacock, http://www.goloka.com/index.html)) |
Key points: The mirage of Martian canals; comparison of Mars with Earth; evidence for water, search for life
|
(to left, from SEDS, http://www.seds.org/nineplanets/nineplanets/mars.html above, Mangala, the planet Mars, depicted as a red-skinned horseman on a white ram. from The Black Peacock, http://www.goloka.com/index.html)) |
We now know that the polar caps are predominately CO2 and not water; the variations in mid-latitude features are due to seasonal dust storms. The infamous “canals” are the result of an optical illusion where the human brain likes to play “connect-the-dots”.
| Mars Orbiter missions in late '60s and early '70s revealed a barren and cratered landscape on Mars making life as we know it on Earth unlikely. However, the areas mapped first have turned out to be the oldest, least "interesting" of the whole Martian surface! |  |
| Later missions have shown much more interesting terrain.
For example, Candor Chasma is a region containing many
landslides, fractured blocks that were probably at the bottoms of ancient lakes, and
craters partially buried by wind-blown sand. Volcanic deposits of lava are present
elsewhere in the canyon. (Image from NASA and NASM, http://www.nasm.edu/ceps/etp/mars/surface/canyons.html)
|
 |
This complex, in some ways earth-like, planetary surface has encouraged continued searches for life, but now on a bacterial and possibly extinct level - and also searches for water, as a necessary condition for formation of life. We will discuss these modern searches later, in the overall context of the formation of life. We now turn to the study of the planet itself.
Mars is smaller and less dense than the earth, and as a result has much lower surface gravity. The appearance of Mars is dominated by iron oxide (rust) that gives it a reddish color.
Mars has huge shield volcanoes, like those in Hawaii (such as Mauna Kea) -- Olympus Mons shown below is larger than any mountain on Earth,
 |
 |
The Martian volcanos grew to huge size because there are no plate motions on Mars (From U. Tenn, http://csep10.phys.utk.edu/astr161/lect/mars/surface.html)
The lack of plate tectonics is confirmed by a lack of marsquakes that can be detected by various Martian lander spacecraft.
Mars also has a huge canyon, Valles Marineris, visible in the whole-disk image at
the top, in the view to the below left, and the artist's concept to the below right. (from
NASA, http://www.units.muohio.edu/dragonfly/space/VALLES.shtml,
Robert Hurt, http://homepage.mac.com/rhurt/gallery/latest.html).
It is far larger than the Grand Canyon. Here is an imaginary flight over
these features Caution! Large File!!
(from http://themis.asu.edu/valles_video Mars
Odyssey Mission Thermal Emission Imaging System, ASU and JPL Digital Image Animation
Laboratory) If you missed the movie, or want to review what you saw, look here 
 |
 |
The escape velocity from the surface of Mars is less than 1/2 that on Earth. The atmosphere’s density is about 1/200th that on Earth. As we would expect given the low escape velocity, the atmospheric composition is dominated by heavier gases than for Earth -- CO2, Argon, H2O.
 |
 |
| Surface is extensively modified by winds,blowing dust. Notice streaks of dust from craters (left). Martian sunset from Mars Pathfinder (right) shows the effect of dust in the atmosphere: (http://www.spacedaily.com/news/mars-odyssey-01b.html) | |
Thin clouds form in the atmosphere. |
 http://www.ucls.uchicago.edu/students/projects/martiansuntimes/ |
 |
Olympus Mons in a dust storm, artist's concept (Brian
Smallwood, http://www.firstinspired.com/spaceprime/space/olympus.htm)
|
 |
Chart of temperatures from Mars Pathfinder -- a Sol is a
Martian day. Days are similar to Earth, seasons more extreme (and colder) because Mars’ orbit is more eccentric than the earth’s and Mars’ polar axis tilt is a little more than for the earth’s (25.2o as compared to Earth’s 23.5o) |
 |
Polar caps are water and dry ice (frozen CO2). (animation adapted by G. Rieke from one provided by STScI) |
 |
(From Mars Global Surveyor, http://www.msss.com/mars_images/moc/4_27_00_spcap/index.html) |
Although the atmosphere and weather conditions do not seem conducive to life now, perhaps the lighter gases leaked away slowly. Is it possible that Mars started with Earth-like conditions, such as flowing water? If so, did life form then?
Valles Marineris and other geological features provide strong evidence for running water on surface in the past.
 |
 |
 |
Rivers and arroyos (above)(from Calvin J. Hamilton,
Solarviews, http://www.solarviews.com/cap/mars/network.htm) Gullies in a crater wall (left), from Mars Global Surveyor, http://www.msss.com/The_MOC_Shop/order_form Dust devils sweep across the Martian desert in this movie clip from the Mars Rovers http://marsrovers.jpl.nasa.gov/gallery/press/spirit/20050819a.html
|
 |
 Crater (to left; diameter about 20 miles) that appears to have been a lake in the past. It has a very smooth, flat floor with "shoreline" markings and streams bringing water in and out as indicated by the arrows. (From Cabrol & Grin, 1999 Icarus); artist's concept (above) shows how it might have looked (from Berkeley Lab, http://www.lbl.gov/Science-Articles/Archive/SB-ESD-hunting-for-martians.html
|
| This beautiful image of the Victoria Crater is from the HIRISE camera
(provided by the U. of Arizona) on the Mars Reconnaisance Orbiter. The original image can
distinguish details at the scale of a few feet. http://marsprogram.jpl.nasa.gov/mro/gallery/press/ The crater is about 800 meters (half a mile) in diameter. The distinctive scalloped shape of the rim is caused by erosion and downhill slides of crater wall material. Boulders that have fallen from the crater wall can be seen at the bottom of the crater. A striking field of sand dunes also lies on the crater floor. The Opportunity rover is perched on the rim of the crater at about the ten o'clock position. See the blow-up below for a better view of it.
|
 |
The Mars Odyssey mission has found that the planet used to have large amounts of water (using an instrument whose development was led by UA Professor Bill Boynton).
 |
Here is how the Odyssey experiment works: When cosmic rays strike the surface of Mars, they can penetrate and react with the atomic nuclei trapped just below. The reaction produces gamma rays with energies characteristic of the atom that produced them. By measuring the gamma rays, we can tell what the atoms below the surface are. From Mars Odyssey home page, http://mars.jpl.nasa.gov/odyssey/ |
 |
The surface areas colored blue show lots of subsurface hydrogen,
indicating the presence of water. Maybe they are telling us where Mars used to have
oceans! From Mars Odyssey home page, http://mars.jpl.nasa.gov/odyssey/ |
Terraforming Mars
 |
 |
 |
Conditions are similar enough to Earth that some have proposed ways we
might modify them to make Mars more habitable -- a process that has been named
"terraforming". Basically, the proposals are based on enhancing greenhouse gases
in the Martian atmosphere to raise the surface temperature. For an explanation of how it
might be done, see http://www.cem.msu.edu/~cem181fp/mars/chem-intro.html,
and many other web sites. It isn't clear at all that this is feasible, of course, nor that
it is desirable
Mars has two moons, Phobos and Deimos, which probably are captured asteroids and did not form with Mars.(from NASA via http://sci.esa.int/science-e/www/object/index.cfm?fobjectid=31031)
 |
 |
Test your understanding before going on
 Mayan Venus deity, from
the Borgia Codex, http://members.shaw.ca/mjfinley/4VENUS.htm |
|
Marduk, associated with Jupiter by the Babylonians |
Click to return to syllabus |
||
| Click to return to Venus | hypertext |
Click to go to Jupiter |
G. H. Rieke