Geology of Mars

Generalised geological map of Mars[1]
Mars as seen by the Hubble Space Telescope

The geology of Mars is the scientific study of the surface, crust, and interior of the planet Mars. It emphasizes the composition, structure, history, and physical processes that shape the planet. It is analogous to the field of terrestrial geology. In planetary science, the term geology is used in its broadest sense to mean the study of the solid parts of planets and moons. The term incorporates aspects of geophysics, geochemistry, mineralogy, geodesy, and cartography.[2] A neologism, areology, from the Greek word Arēs (Mars), sometimes appears as a synonym for Mars's geology in the popular media and works of science fiction (e.g. Kim Stanley Robinson’s Mars trilogy),[3] but the term is rarely, if ever, used by professional geologists and planetary scientists.[4]

Geological map of Mars (2014)

Mars - geologic map (USGS; July 14, 2014) (full image)[5][6][7]

Global Martian topography and large-scale features

Acidalia Planitia Acidalia Planitia Alba Mons Amazonis Planitia Aonia Terra Arabia Terra Arcadia Planitia Arcadia Planitia Argyre Planitia Elysium Mons Elysium Planitia Hellas Planitia Hesperia Planum Isidis Planitia Lucas Planum Lyot Crater Noachis Terra Olympus Mons Promethei Terra Rudaux Crater Solis Planum Tempe Terra Terra Cimmeria Terra Sabaea Terra Sirenum Tharsis Montes Utopia Planitia Valles Marineris Vastitas Borealis Vastitas BorealisMap of Mars
Interactive imagemap of the global topography of Mars, overlain with locations of Mars landers and rovers (Red label = Rover; Blue label = Lander; bold red/blue = currently active). Hover your mouse to see the names of over 25 prominent geographic features, and click to link to them. Coloring of the base map indicates relative elevations, based on data from the Mars Orbiter Laser Altimeter on NASA's Mars Global Surveyor. Reds and pinks are higher elevation (+3 km to +8 km); yellow is 0 km; greens and blues are lower elevation (down to −8 km). Whites (>+12 km) and browns (>+8 km) are the highest elevations. Axes are latitude and longitude; Poles are not shown.
(also see: Mars map & Mars Memorials & Mars Memorials map) (view • discuss)
Beagle 2 (2003)
Curiosity (2012) →
Deep Space 2 (1999)
Mars 2 (1971)
Mars 3 (1971)
Mars 6 (1973)
Polar Lander (1999)
Opportunity (2004)
Phoenix (2008)
Schiaparelli EDM (2016)
Sojourner (1997)
Spirit (2004)
Viking 1 (1976)
Viking 2 (1976)

Composition of Mars

Main article: Composition of Mars

Mars is a differentiated, terrestrial planet.

Global physiography

Most of our current knowledge about the geology of Mars comes from studying landforms and relief features (terrain) seen in images taken by orbiting spacecraft. Mars has a number of distinct, large-scale surface features that indicate the types of geological processes that have operated on the planet over time. This section introduces several of the larger physiographic regions of Mars. Together, these regions illustrate how geologic processes involving volcanism, tectonism, water, ice, and impacts have shaped the planet on a global scale.

Hemispheric dichotomy

Main article: Martian dichotomy
Mars Orbital Laser Altimeter (MOLA) colorized shaded-relief maps showing elevations in the western and eastern hemispheres of Mars. (Left): The western hemisphere is dominated by the Tharsis region (red and brown). Tall volcanoes appear white. Valles Marineris (blue) is the long gash-like feature to the right. (Right): Eastern hemisphere shows the cratered highlands (yellow to red) with the Hellas basin (deep blue/purple) at lower left. The Elysium province is at the upper right edge. Areas north of the dichotomy boundary appear as shades of blue on both maps.

The northern and southern hemispheres of Mars are strikingly different from each other in topography and physiography. This dichotomy is a fundamental global geologic feature of the planet. Simply stated, the northern part of the planet is an enormous topographic depression. About one-third of the planet’s surface (mostly in the northern hemisphere) lies 3–6 km lower in elevation than the southern two-thirds. This is a first-order relief feature on par with the elevation difference between Earth’s continents and ocean basins.[8] The dichotomy is also expressed in two other ways: as a difference in impact crater density and crustal thickness between the two hemispheres.[9] The hemisphere south of the dichotomy boundary (often called the southern highlands or uplands) is very heavily cratered and ancient, characterized by rugged surfaces that date back to the period of heavy bombardment. In contrast, the lowlands north of the dichotomy boundary have few large craters, are very smooth and flat, and have other features indicating that extensive resurfacing has occurred since the southern highlands formed. The third distinction between the two hemispheres is in crustal thickness. Topographic and geophysical gravity data indicate that the crust in the southern highlands has a maximum thickness of about 58 km (36 mi), whereas crust in the northern lowlands "peaks" at around 32 km (20 mi) in thickness.[10][11] The location of the dichotomy boundary varies in latitude across Mars and depends on which of the three physical expressions of the dichotomy is being considered.

The origin and age of the hemispheric dichotomy are still debated. Hypotheses of origin generally fall into two categories: one, the dichotomy was produced by a mega-impact event or several large impacts early in the planet’s history (exogenic theories)[12][13][14] or two, the dichotomy was produced by crustal thinning in the northern hemisphere by mantle convection, overturning, or other chemical and thermal processes in the planet’s interior (endogenic theories).[15][16] One endogenic model proposes an early episode of plate tectonics producing a thinner crust in the north, similar to what is occurring at spreading plate boundaries on Earth.[17] Whatever its origin, the Martian dichotomy appears to be extremely old. A new theory based on the Southern Polar Giant Impact[18] and validated by the discovery of twelve hemispherical alignments[19] shows that exogenic theories appear to be stronger than endogenic theories and that Mars never had plate tectonics[20][21] that could modify the dichotomy. Laser altimeter and radar sounding data from orbiting spacecraft have identified a large number of basin-sized structures previously hidden in visual images. Called quasi-circular depressions (QCDs), these features likely represent derelict impact craters from the period of heavy bombardment that are now covered by a veneer of younger deposits. Crater counting studies of QCDs suggest that the underlying surface in the northern hemisphere is at least as old as the oldest exposed crust in the southern highlands.[22] The ancient age of the dichotomy places a significant constraint on theories of its origin.[23]

Tharsis and Elysium volcanic provinces

Straddling the dichotomy boundary in Mars's western hemisphere is a massive volcano-tectonic province known as the Tharsis region or the Tharsis bulge. This immense, elevated structure is thousands of kilometers in diameter and covers up to 25% of the planet’s surface.[24] Averaging 7–10 km above datum (Martian "sea" level), Tharsis contains the highest elevations on the planet and the largest known volcanoes in the Solar System. Three enormous volcanoes, Ascraeus Mons, Pavonis Mons, and Arsia Mons (collectively known as the Tharsis Montes), sit aligned NE-SW along the crest of the buldge. The vast Alba Mons (formerly Alba Patera) occupies the northern part of the region. The huge shield volcano Olympus Mons lies off the main buldge, at the western edge of the province. The extreme massiveness of Tharsis has placed tremendous stresses on the planet’s lithosphere. As a result, immense extensional fractures (grabens and rift valleys) radiate outward from Tharsis, extending halfway around the planet.[25]

A smaller volcanic center lies several thousand kilometers west of Tharsis in Elysium. The Elysium volcanic complex is about 2,000 kilometers in diameter and consists of three main volcanoes, Elysium Mons, Hecates Tholus, and Albor Tholus. The Elysium group of volcanoes is thought to be somewhat different from the Tharsis Montes, in that development of the former involved both lavas and pyroclastics.[26]

Large impact basins

Several enormous, circular impact basins are present on Mars. The largest one that is readily visible is the Hellas basin located in the southern hemisphere. It is the second largest confirmed impact structure on the planet, centered at about 64°E longitude and 40°S latitude. The central part of the basin (Hellas Planitia) is 1,800 km in diameter[27] and surrounded by a broad, heavily eroded annular rim structure characterized by closely spaced rugged irregular mountains (massifs), which probably represent uplifted, jostled blocks of old pre-basin crust.[28] (See Anseris Mons, for example.) Ancient, low-relief volcanic constructs (highland paterae) are located on the northeastern and southwestern portions of the rim. The basin floor contains thick, structurally complex sedimentary deposits that have a long geologic history of deposition, erosion, and internal deformation. The lowest elevations on the planet are located within the Hellas basin, with some areas of the basin floor lying over 8 km below datum.[29]

The two other large impact structures on the planet are the Argyre and Isidis basins. Like Hellas, Argyre (800 km in diameter) is located in the southern highlands and is surrounded by a broad ring of mountains. The mountains in the southern portion of the rim, Charitum Montes, may have been eroded by valley glaciers and ice sheets at some point in Mars's history.[30] The Isidis basin (roughly 1,000 km in diameter) lies on the dichotomy boundary at about 87°E longitude. The northeastern portion of the basin rim has been eroded and is now buried by northern plains deposits, giving the basin a semicircular outline. The northwestern rim of the basin is characterized by arcuate grabens (Nili Fossae) that are circumferential to the basin. One additional large basin, Utopia, is completely buried by northern plains deposits. Its outline is clearly discernable only from altimetry data. All of the large basins on Mars are extremely old, dating back to the late heavy bombardment. They are thought to be comparable in age to the Imbrium and Orientale basins on the Moon.

Equatorial canyon system

Viking Orbiter 1 view image of Valles Marineris.

Near the equator in the western hemisphere lies an immense system of deep, interconnected canyons and troughs collectively known as the Valles Marineris. The canyon system extends eastward from Tharsis for a length of over 4,000 km, nearly a quarter of the planet’s circumference. If placed on Earth, Valles Marineris would span the width of North America.[31] In places, the canyons are up to 300 km wide and 10 km deep. Often compared to Earth’s Grand Canyon, the Valles Marineris has a very different origin than its tinier, so-called counterpart on Earth. The Grand Canyon is largely a product of water erosion. The Martian equatorial canyons were of tectonic origin, i.e. they were formed mostly by faulting. They could be similar to the East African Rift valleys.[32] The canyons represent the surface expression of powerful extensional strain in the Martian crust, probably due to loading from the Tharsis bulge.[33]

Chaotic terrain and outflow channels

The terrain at the eastern end of the Valles Marineris grades into dense jumbles of low rounded hills that seem to have formed by the collapse of upland surfaces to form broad, rubble-filled hollows.[34] Called chaotic terrain, these areas mark the heads of huge outflow channels that emerge full size from the chaotic terrain and empty (debouch) northward into Chryse Planitia. The presence of streamlined islands and other geomorphic features indicate that the channels were most likely formed by catastrophic releases of water from aquifers or the melting of subsurface ice. However, these features could also be formed by abundant volcanic lava flows coming from Tharsis.[35] The channels, which include Ares, Shalbatana, Simud, and Tiu Valles, are enormous by terrestrial standards, and the flows that formed them correspondingly immense. For example, the peak discharge required to carve the 28-km-wide Ares Vallis is estimated to have been 500 million cubic feet per second, over ten thousand times the average discharge of the Mississippi River.[36]

Mars Orbital Laser Altimeter (MOLA) derived image of Planum Boreum. Vertical exaggeration is extreme. Note that residual ice cap is only the thin veneer (shown in white) on top of the plateau.

Ice caps

The polar ice caps are well-known telescopic features of Mars, first identified by Christiaan Huygens in 1672.[37] Since the 1960s, we have known that the seasonal caps (those seen in the telescope to grow and wane seasonally) are composed of carbon dioxide (CO2) ice that condenses out of the atmosphere as temperatures fall to 148 K, the frost point of CO2, during the polar wintertime.[38] In the north, the CO2 ice completely dissipates (sublimes) in summer, leaving behind a residual cap of water (H2O) ice. At the south pole, a small residual cap of CO2 ice remains in summer.

Both residual ice caps overlie thick layered deposits of interbedded ice and dust. In the north, the layered deposits form a 3 km-high, 1,000 km-diameter plateau called Planum Boreum. A similar kilometers-thick plateau, Planum Australe, lies in the south. Both plana (the Latin plural of planum) are sometimes treated as synonymous with the polar ice caps, but the permanent ice (seen as the high albedo, white surfaces in images) forms only a relatively thin mantle on top of the layered deposits. The layered deposits probably represent alternating cycles of dust and ice deposition caused by climate changes related to variations in the planet's orbital parameters over time (see also Milankovitch cycles). The polar layered deposits are some of the youngest geologic units on Mars.

Geologic history

Albedo features

Mollweide projection of albedo features on Mars from Hubble Space Telescope. Bright ochre areas in left, center, and right are Tharsis, Arabia, and Elysium, respectively. The dark region at top center left is Acidalium Planitia. Syrtis Major is the dark area projecting upward in the center right. Note orographic clouds over Olympus and Elysium Montes (left and right, respectively).
Main article: Martian surface

No topography is visible on Mars from Earth. The bright areas and dark markings seen through a telescope are albedo features. The bright, red-ochre areas are locations where fine dust covers the surface. Bright areas (excluding the polar caps and clouds) include Hellas, Tharsis, and Arabia Terra. The dark gray markings represent areas that the wind has swept clean of dust, leaving behind the lower layer of dark, rocky material. Dark markings are most distinct in a broad belt from 0° to 40° S latitude. However, the most prominent dark marking, Syrtis Major Planum, is in the northern hemisphere.[39] The classical albedo feature, Mare Acidalium (Acidalia Planitia), is another prominent dark area in the northern hemisphere. A third type of area, intermediate in color and albedo, is also present and thought to represent regions containing a mixture of the material from the bright and dark areas.[40]

Impact craters

Impact craters were first identified on Mars by the Mariner 4 spacecraft in 1965.[41] Early observations showed that Martian craters were generally shallower and smoother than lunar craters, indicating that Mars has a more active history of erosion and deposition than the Moon.[42]

In other aspects, Martian craters resemble lunar craters. Both are products of hypervelocity impacts and show a progression of morphology types with increasing size. Martian craters below about 7 km in diameter are called simple craters; they are bowl-shaped with sharp raised rims and have depth/diameter ratios of about 1/5.[43] Martian craters change from simple to more complex types at diameters of roughly 5 to 8 km. Complex craters have central peaks (or peak complexes), relatively flat floors, and terracing or slumping along the inner walls. Complex craters are shallower than simple craters in proportion to their widths, with depth/diameter ratios ranging from 1/5 at the simple-to-complex transition diameter (~7 km) to about 1/30 for a 100-km diameter crater. Another transition occurs at crater diameters of around 130 km as central peaks turn into concentric rings of hills to form multi-ring basins.[44]

Mars has the greatest diversity of impact crater types of any planet in the Solar System.[45] This is partly because the presence of both rocky and volatile-rich layers in the subsurface produces a range of morphologies even among craters within the same size classes. Mars also has an atmosphere that plays a role in ejecta emplacement and subsequent erosion. Moreover, Mars has a rate of volcanic and tectonic activity low enough that ancient, eroded craters are still preserved, yet high enough to have resurfaced large areas of the planet, producing a diverse range of crater populations of widely differing ages. Over 42,000 impact craters greater than 5 km in diameter have been catalogued on Mars,[46] and the number of smaller craters is probably innumerable. The density of craters on Mars is highest in the southern hemisphere, south of the dichotomy boundary. This is where most of the large craters and basins are located.

Crater morphology provides information about the physical structure and composition of the surface and subsurface at the time of impact. For example, the size of central peaks in Martian craters is larger than comparable craters on Mercury or the Moon.[47] In addition, the central peaks of many large craters on Mars have pit craters at their summits. Central pit craters are rare on the Moon but are very common on Mars and the icy satellites of the outer Solar System. Large central peaks and the abundance of pit craters probably indicate the presence of near-surface ice at the time of impact.[45] Polewards of 30 degrees of latitude, the form of older impact craters is rounded out ("softened") by acceleration of soil creep by ground ice.[48]

The most notable difference between Martian craters and other craters in the Solar System is the presence of lobate (fludized) ejecta blankets. Many craters at equatorial and mid-latitudes on Mars have this form of ejecta morphology, which is thought to arise when the impacting object melts ice in the subsurface. Liquid water in the ejected material forms a muddy slurry that flows along the surface, producing the characteristic lobe shapes.[49][50] The crater Yuty is a good example of a rampart crater, which is so called because of the rampart-like edge to its ejecta blanket.[51]

Martian craters are commonly classified by their ejecta. Craters with one ejecta layer are called single-layer ejecta (SLE) craters. Craters with two superposed ejecta blankets are called double-layer ejecta (DLE) craters, and craters with more than two ejecta layers are called multiple-layered ejecta (MLE) craters. These morphological differences are thought to reflect compositional differences (i.e. interlayered ice, rock, or water) in the subsurface at the time of impact.[52][53]

Pedestal crater in Amazonis quadrangle as seen by HiRISE.

Martian craters show a large diversity of preservational states, from extremely fresh to old and eroded. Degraded and infilled impact craters record variations in volcanic, fluvial, and eolian activity over geologic time.[54] Pedestal craters are craters with their ejecta sitting above the surrounding terrain to form raised platforms. They occur because the crater's ejecta forms a resistant layer so that the area nearest the crater erodes more slowly than the rest of the region. Some pedestals are hundreds of meters above the surrounding area, meaning that hundreds of meters of material were eroded away. Pedestal craters were first observed during the Mariner 9 mission in 1972.[55][56][57]

Further information: Impact crater
Further information: List of craters on Mars
Further information: Rampart crater

Volcanism

Main article: Volcanism on Mars

Volcanic structures and landforms cover large portions of the Martian surface. The most conspicuous volcanoes on Mars occur in Tharsis and Elysium. Geologists think one of the reasons that volcanoes on Mars are able to grow so large is because Mars has sparsely few tectonic boundaries compared to Earth.[59] Lava from a stationary hot spot is able to accumulate at one location on the surface for many hundreds of millions of years.

On October 17, 2012, the Curiosity rover on the planet Mars at "Rocknest" performed the first X-ray diffraction analysis of Martian soil. The results from the rover's CheMin analyzer revealed the presence of several minerals, including feldspar, pyroxenes and olivine, and suggested that the Martian soil in the sample was similar to the "weathered basaltic soils" of Hawaiian volcanoes.[58] In July 2015, the same rover identified tridymite in a rock sample from Gale Crater, leading scientists to believe that silicic volcanism might have played a much more prevalent role in the planet's volcanic history than previously thought. [60]

Sedimentology

See also: Water on Mars
Collection of spheres, each about 3 mm in diameter as seen by Opportunity rover

Flowing water appears to have been common on the surface of Mars at various points in its history, and especially on ancient Mars.[61] Many of these flows carved the surface, forming valley networks and producing sediment. This sediment has been redeposited in a wide variety of wet environments, including in alluvial fans, meandering channels, deltas, lakes, and perhaps even oceans.[62][63][64] The processes of deposition and transportation are associated with gravity. Due to gravity, related differences in water fluxes and flow speeds, inferred from grain size distributions, Martian landscapes were created by different environmental conditions.[65] Nevertheless, there are other ways of estimating the amount of water on ancient Mars (see: Water on Mars). Groundwater has been implicated in the cementation of aeolian sediments and the formation and transport of a wide variety of sedimentary minerals including clays, sulphates and hematite.[66]

When the surface has been dry, wind has been a major geomorphic agent. Wind driven sand bodies like megaripples and dunes are extremely common on the modern Martian surface, and Opportunity has documented abundant aeolian sandstones on its traverse.[67] Ventifacts, like Jake Matijevic (rock), are an other aeolian landform on the Martian Surface.[68]

A wide variety of other sedimentological facies are also present locally on Mars, including glacial deposits, hot springs, dry mass movement deposits (especially landslides), and cryogenic and periglacial material, amongst many others.[62]

Common surface features

Groundwater on Mars

One group of researchers proposed that some of the layers on Mars were caused by groundwater rising to the surface in many places, especially inside of craters. According to the theory, groundwater with dissolved minerals came to the surface, in and later around craters, and helped to form layers by adding minerals (especially sulfate) and cementing sediments. This hypothesis is supported by a groundwater model and by sulfates discovered in a wide area.[69][70] At first, by examining surface materials with Opportunity Rover, scientists discovered that groundwater had repeatedly risen and deposited sulfates.[66][71][72][73][74] Later studies with instruments on board the Mars Reconnaissance Orbiter showed that the same kinds of materials exist in a large area that included Arabia.[75]

Interesting geological features

Avalanches

On February 19, 2008, images obtained by the HiRISE camera on the Mars Reconnaissance Orbiter showed a spectacular avalanche, in which debris thought to be fine-grained ice, dust, and large blocks fell from a 700-metre (2,300 ft) high cliff. Evidence of the avalanche included dust clouds rising from the cliff afterwards.[76] Such geological events are theorized to be the cause of geologic patterns known as slope streaks.

Possible Caves

NASA scientists studying pictures from the Odyssey spacecraft have spotted what might be seven caves on the flanks of the Arsia Mons volcano on Mars. The pit entrances measure from 100 to 252 metres (328 to 827 ft) wide and they are believed to be at least 73 to 96 metres (240 to 315 ft) deep. See image below: the pits have been informally named (A) Dena, (B) Chloe, (C) Wendy, (D) Annie, (E) Abby (left) and Nikki, and (F) Jeanne. Because light did not reach the floor of most of the pits, it is likely that they extend much deeper than these lower estimates. Dena's floor was observed and found to be 130m deep.[77] Further investigation suggested that these were not necessarily lava tube "skylights".[78] Review of the images has resulted in yet more discoveries of deep pits.[79]

It has been suggested that human explorers on Mars could use lava tubes as shelters. The caves may be the only natural structures offering protection from the micrometeoroids, UV radiation, solar flares, and high energy particles that bombard the planet's surface.[80]

Inverted relief

Some areas of Mars show inverted relief, where features that were once depressions, like streams, are now above the surface. It is believed that materials like large rocks were deposited in low-lying areas. Later, wind erosion removed much of the surface layers, but left behind the more resistant deposits. Other ways of making inverted relief might be lava flowing down a stream bed or materials being cemented by minerals dissolved in water. On Earth, materials cemented by silica are highly resistant to all kinds of erosional forces. Examples of inverted channels on Earth are found in the Cedar Mountain Formation near Green River, Utah. Inverted relief in the shape of streams are further evidence of water flowing on the Martian surface in past times.[81] Inverted relief in the form of stream channels suggest that the climate was different—much wetter—when the inverted channels were formed.

In an article published in January 2010, a large group of scientists endorsed the idea of searching for life in Miyamoto Crater because of inverted stream channels and minerals that indicated the past presence of water.[82]

Images of other examples of inverted terrain are shown below from various parts of Mars.

Notable rocks on Mars
Adirondack
(Spirit)
Barnacle Bill
(Sojourner)
Bathurst Inlet
(Curiosity)
Big Joe*
(Viking)
Block Island
(Opportunity) M
Bounce
(Opportunity)
Coronation
(Curiosity)
El Capitan
(Opportunity)
Esperance*
(Opportunity)
Goulburn
(Curiosity)
Heat Shield
(Opportunity) M
Home Plate
(Spirit)
Hottah
(Curiosity)
Jake Matijevic
(Curiosity)
Last Chance
(Opportunity)
Link
(Curiosity)
Mackinac Island
(Opportunity) M
Mimi*
(Spirit)
Oileán Ruaidh
(Opportunity) M
Pot of Gold
(Spirit)
Rocknest 3
(Curiosity)
Shelter Island
(Opportunity) M
Tintina
(Curiosity)
Yogi
(Sojourner)
Notes: * = linked article is about the mission that encountered this rock; M = Meteorite - ()

See also

References

  1. P. Zasada (2013) Generalised Geological Map of Mars, 1:140.000.000, Source Link.
  2. Greeley, Ronald (1993). Planetary landscapes (2nd ed.). New York: Chapman & Hall. p. 1. ISBN 0-412-05181-8.
  3. Quinion, M. (1996). World Wide Words Website, http://www.worldwidewords.org/turnsofphrase/tp-are1.htm.
  4. Carr, M.H., USGS, Personal Communication, September 13, 2010.
  5. Tanaka, Kenneth L.; Skinner, James A., Jr.; Dohm, James M.; Irwin, Rossman P., III; Kolb, Eric J.; Fortezzo, Corey M.; Platz, Thomas; Michael, Gregory G.; Hare, Trent M. (July 14, 2014). "Geologic Map of Mars - 2014". USGS. Retrieved July 22, 2014.
  6. Krisch, Joshua A. (July 22, 2014). "Brand New Look at the Face of Mars". New York Times. Retrieved July 22, 2014.
  7. Staff (July 14, 2014). "Mars - Geologic map - Video (00:56)". USGS. Retrieved July 22, 2014.
  8. Watters, Thomas R.; McGovern, Patrick J.; Irwin Iii, Rossman P. (2007). "Hemispheres Apart: The Crustal Dichotomy on Mars" (PDF). Annu. Rev. Earth Planet. Sci. 35 (1): 621–652 [624, 626]. Bibcode:2007AREPS..35..621W. doi:10.1146/annurev.earth.35.031306.140220.
  9. Carr 2006, pp. 78–79
  10. Zuber, M. T.; Solomon, SC; Phillips, RJ; Smith, DE; Tyler, GL; Aharonson, O; Balmino, G; Banerdt, WB; et al. (2000). "Internal Structure and Early Thermal Evolution of Mars from Mars Global Surveyor Topography and Gravity". Science. 287 (5459): 1788–93. Bibcode:2000Sci...287.1788Z. doi:10.1126/science.287.5459.1788. PMID 10710301.
  11. Neumann, G. A. (2004). "Crustal structure of Mars from gravity and topography". Journal of Geophysical Research. 109 (E8). Bibcode:2004JGRE..10908002N. doi:10.1029/2004JE002262.
  12. Wilhelms, D.E.; Squyres, S.W. (1984). "The Martian Hemispheric Dichotomy May Be Due to a Giant Impact". Nature. 309 (5964): 138–140. Bibcode:1984Natur.309..138W. doi:10.1038/309138a0.
  13. Frey, Herbert; Schultz, Richard A. (1988). "Large impact basins and the mega‐impact origin for the crustal dichotomy on Mars". Geophysical Research Letters. 15 (3): 229–232. Bibcode:1988GeoRL..15..229F. doi:10.1029/GL015i003p00229.
  14. Andrews-Hanna, J.C.; et al. (2008). "The Borealis Basin and the Origin of the Martian Crustal Dichotomy". Nature. 453 (7199). pp. 1212–5; see p. 1212. Bibcode:2008Natur.453.1212A. doi:10.1038/nature07011. PMID 18580944.
  15. Wise, Donald U.; Golombek, Matthew P.; McGill, George E. (1979). "Tectonic Evolution of Mars". Journal of Geophysical Research. 84 (B14): 7934–7939. Bibcode:1979JGR....84.7934W. doi:10.1029/JB084iB14p07934.
  16. Elkins-Tanton, Linda T.; Hess, Paul C.; Parmentier, E. M. (2005). "Possible formation of ancient crust on Mars through magma ocean processes" (PDF). Journal of Geophysical Research. 110 (E12): E120S01. Bibcode:2005JGRE..11012S01E. doi:10.1029/2005JE002480.
  17. Sleep, Norman H. (1994). "Martian plate tectonics". Journal of Geophysical Research. 99 (E3): 5639–5655. Bibcode:1994JGR....99.5639S. doi:10.1029/94JE00216.
  18. Leone, Giovanni; Tackley, Paul J.; Gerya, Taras V.; May, Dave A.; Zhu, Guizhi (2014-12-28). "Three-dimensional simulations of the southern polar giant impact hypothesis for the origin of the Martian dichotomy". Geophysical Research Letters. 41 (24): 2014GL062261. doi:10.1002/2014GL062261. ISSN 1944-8007.
  19. Leone, Giovanni (2016-01-01). "Alignments of volcanic features in the southern hemisphere of Mars produced by migrating mantle plumes". Journal of Volcanology and Geothermal Research. 309: 78–95. doi:10.1016/j.jvolgeores.2015.10.028.
  20. O’Rourke, Joseph G.; Korenaga, Jun (2012-11-01). "Terrestrial planet evolution in the stagnant-lid regime: Size effects and the formation of self-destabilizing crust". Icarus. 221 (2): 1043–1060. doi:10.1016/j.icarus.2012.10.015.
  21. Wong, Teresa; Solomatov, Viatcheslav S (2015-07-02). "Towards scaling laws for subduction initiation on terrestrial planets: constraints from two-dimensional steady-state convection simulations". Progress in Earth and Planetary Science. 2 (1). doi:10.1186/s40645-015-0041-x. ISSN 2197-4284.
  22. Watters, T.R.; McGovern, Patrick J.; Irwin, R.P. (2007). "Hemispheres Apart: The Crustal Dichotomy on Mars". Annu. Rev. Earth Planet. Sci. 35: 630–635. Bibcode:2007AREPS..35..621W. doi:10.1146/annurev.earth.35.031306.140220.
  23. Solomon, S. C.; Aharonson, O; Aurnou, JM; Banerdt, WB; Carr, MH; Dombard, AJ; Frey, HV; Golombek, MP; et al. (2005). "New Perspectives on Ancient Mars". Science. 307 (5713): 1214–20. Bibcode:2005Sci...307.1214S. doi:10.1126/science.1101812. PMID 15731435.
  24. Solomon, Sean C.; Head, James W. (1982). "Evolution of the Tharsis Province of Mars: The Importance of Heterogeneous Lithospheric Thickness and Volcanic Construction". J. Geophys. Res. 87 (B12): 9755–9774. Bibcode:1982JGR....87.9755S. doi:10.1029/JB087iB12p09755.
  25. Carr, M.H (2007). Mars: Surface and Interior in Encyclopedia of the Solar System, 2nd ed., McFadden, L.-A. et al. Eds. Elsevier: San Diego, CA, p.319
  26. Cattermole, Peter John (2001). Mars: the mystery unfolds. Oxford: Oxford University Press. p. 71. ISBN 0-19-521726-8.
  27. Boyce, J.M. (2008) The Smithsonian Book of Mars; Konecky&Konecky: Old Saybrook, CT, p. 13.
  28. Carr, M.H.; Saunders, R.S.; Strom R.G. (1984). Geology of the Terrestrial Planets; NASA Scientific and Technical Information Branch: Washington DC, 1984, p. 223. http://www.lpi.usra.edu/publications/books/geologyTerraPlanets/
  29. Hartmann 2003, pp. 70–73
  30. Kargel, J.S.; Strom, R.G. (1992). "Ancient Glaciation on Mars". Geology. 20 (1): 3–7. Bibcode:1992Geo....20....3K. doi:10.1130/0091-7613(1992)020<0003:AGOM>2.3.CO;2.
  31. Kargel, J.S. (2004) Mars: A Warmer Wetter Planet; Springer-Praxis: London, p. 52.
  32. Carr 2006, p. 95
  33. Hartmann 2003, p. 316
  34. Carr 2006, p. 114
  35. Leone, Giovanni (2014-05-01). "A network of lava tubes as the origin of Labyrinthus Noctis and Valles Marineris on Mars". Journal of Volcanology and Geothermal Research. 277: 1–8. doi:10.1016/j.jvolgeores.2014.01.011.
  36. Baker, Victor R. (2001). "Water and the Martian Landscape" (PDF). Nature. 412 (6843). pp. 228–36; see p. 231 Fig. 5. doi:10.1038/35084172. PMID 11449284.
  37. Sheehan, W. (1996). The Planet Mars: A History of Observation & Discovery; University of Arizona Press: Tucson, p. 25. http://www.uapress.arizona.edu/onlinebks/mars/contents.htm.
  38. Leighton, R.B.; Murray, B.C. (1966). "Behavior of Carbon Dioxide and Other Volatiles on Mars". Science. 153 (3732): 136–144. Bibcode:1966Sci...153..136L. doi:10.1126/science.153.3732.136. PMID 17831495.
  39. Carr 2006, p. 1
  40. Arvidson, Raymond E.; Guinness, Edward A.; Dale-Bannister, Mary A.; Adams, John; Smith, Milton; Christensen, Philip R.; Singer, Robert B. (1989). "Nature and Distribution of Surficial Deposits in Chryse Planitia and Vicinity, Mars". J. Geophys. Res. 94 (B2): 1573–1587. Bibcode:1989JGR....94.1573A. doi:10.1029/JB094iB02p01573.
  41. Leighton, R.B.; Murray, B.C.; Sharp, R.P.; Allen, J.D.; Sloan, R.K. (1965). "Mariner IV Photography of Mars: Initial Results". Science. 149 (3684): 627–630. Bibcode:1965Sci...149..627L. doi:10.1126/science.149.3684.627. PMID 17747569.
  42. Leighton, R.B.; Horowitz, NH; Murray, BC; Sharp, RP; Herriman, AH; Young, AT; Smith, BA; Davies, ME; Leovy, CB (1969). "Mariner 6 and 7 Television Pictures: Preliminary Analysis". Science. 166 (3901): 49–67. Bibcode:1969Sci...166...49L. doi:10.1126/science.166.3901.49. PMID 17769751.
  43. Pike, R.J. (1980). "Formation of Complex Impact Craters: Evidence from Mars and Other Planets". Icarus. 43 (1): 1–19 [5]. Bibcode:1980Icar...43....1P. doi:10.1016/0019-1035(80)90083-4.
  44. Carr 2006, pp. 24–27
  45. 1 2 Strom, R.G.; Croft, S.K.; Barlow, N.G. (1992). "The Martian Impact Cratering Record". In Kieffer, H.H.; Jakosky, B.M.; Snyder, C.W.; et al. Mars. Tucson: University of Arizona Press. pp. 384–385. ISBN 978-0-8165-1257-7.
  46. Barlow, N.G. (1988). "Crater Size-Frequency Distributions and a Revised Martian Relative Chronology". Icarus. 75 (2): 285–305. Bibcode:1988Icar...75..285B. doi:10.1016/0019-1035(88)90006-1.
  47. Hale, W.S.; Head, J.W. (1981). Lunar Planet. Sci. XII, pp. 386-388. (abstract 1135). http://www.lpi.usra.edu/meetings/lpsc1981/pdf/1135.pdf
  48. Squyres, Steven W., and Michael H. Carr. "Geomorphic evidence for the distribution of ground ice on Mars." Science 231.4735 (1986): 249-252.
  49. Walter S. Kiefer (2004). "Maximum Impact - Impact Craters in the Solar System". NASA Solar System Exploration. Retrieved 2007-05-14.
  50. Hartmann 2003, pp. 99–100
  51. "Viking Orbiter Views Of Mars". NASA. Retrieved 2007-03-16.
  52. Boyce, J.M. The Smithsonian Book of Mars; Konecky&Konecky: Old Saybrook, CT, 2008, p. 203.
  53. Barlow, N.G.; Boyce, Joseph M.; Costard, Francois M.; Craddock, Robert A.; Garvin, James B.; Sakimoto, Susan E. H.; Kuzmin, Ruslan O.; Roddy, David J.; Soderblom, Laurence A. (2000). "Standardizing the Nomenclature of Martian Impact Crater Ejecta Morphologies". J. Geophys. Res. 105 (E11): 26,733–8. Bibcode:2000JGR...10526733B. doi:10.1029/2000JE001258.
  54. Nadine Barlow. "Stones, Wind and Ice". Lunar and Planetary Institute. Retrieved 2007-03-15.
  55. http://hirise.lpl.eduPSP_008508_1870
  56. Bleacher, J. and S. Sakimoto. Pedestal Craters, A Tool For Interpreting Geological Histories and Estimating Erosion Rates. LPSC
  57. Pedestal Craters in Utopia | Mars Odyssey Mission THEMIS
  58. 1 2 Brown, Dwayne (October 30, 2012). "NASA Rover's First Soil Studies Help Fingerprint Martian Minerals". NASA. Retrieved October 31, 2012.
  59. Wolpert, Stuart (August 9, 2012). "UCLA scientist discovers plate tectonics on Mars". Yin, An. UCLA. Retrieved August 11, 2012.
  60. NASA News (22 June 2016), "NASA Scientists Discover Unexpected Mineral on Mars", NASA Media, retrieved 23 June 2016
  61. Craddock, R.A.; Howard, A.D. (2002). "The case for rainfall on a warm, wet early Mars". J. Geophys. Res. 107 (E11). Bibcode:2002JGRE..107.5111C. doi:10.1029/2001je001505.
  62. 1 2 Carr, M. 2006. The Surface of Mars. Cambridge University Press. ISBN 978-0-521-87201-0
  63. Grotzinger, J. and R. Milliken (eds.) 2012. Sedimentary Geology of Mars. SEPM
  64. Salese, F., G. Di Achille, A. Neesemann, G. G. Ori, and E. Hauber (2016), Hydrological and sedimentary analyses of well-preserved paleofluvial-paleolacustrine systems at Moa Valles, Mars, J. Geophys. Res. Planets, 121, 194–232, doi:10.1002/2015JE004891.
  65. Patrick Zasada (2013/14): Gradation of extraterrestrial fluvial sediments – related to the gravity. - Z. geol. Wiss. 41/42 (3): 167-183. Abstract
  66. 1 2 "Opportunity Rover Finds Strong Evidence Meridiani Planum Was Wet". Retrieved July 8, 2006.
  67. S. W. Squyres and A. H. Knoll, Sedimentary Geology at Meridiani Planum, Mars, Elsevier, Amsterdam, ISBN 978-0-444-52250-4 (2005); reprinted from Earth and Planetary Science Letters, Vol. 240, No. 1 (2005).
  68. Zasada, P., 2013: Entstehung des Marsgesteins "Jake Matijevic". – Sternzeit, issue 2/2013: 98 ff. (in German language).
  69. Andrews-Hanna, J. C.; Phillips, R. J.; Zuber, M. T. (2007). "Meridiani Planum and the global hydrology of Mars". Nature. 446 (7132): 163–166. Bibcode:2007Natur.446..163A. doi:10.1038/nature05594. PMID 17344848.
  70. Andrews; Hanna, J. C.; Zuber, M. T.; Arvidson, R. E.; Wiseman, S. M. (2010). "Early Mars hydrology: Meridiani playa deposits and the sedimentary record of Arabia Terra". J. Geophys. Res. 115: E06002. Bibcode:2010JGRE..115.6002A. doi:10.1029/2009JE003485.
  71. Grotzinger, J. P.; et al. (2005). "Stratigraphy and sedimentology of a dry to wet eolian depositional system, Burns formation, Meridiani Planum, Mars". Earth Planet. Sci. Lett. 240: 11–72. Bibcode:2005E&PSL.240...11G. doi:10.1016/j.epsl.2005.09.039.
  72. McLennan, S. M.; et al. (2005). "Provenance and diagenesis of the evaporitebearing Burns formation, Meridiani Planum, Mars". Earth Planet. Sci. Lett. 240: 95–121. Bibcode:2005E&PSL.240...95M. doi:10.1016/j.epsl.2005.09.041.
  73. Squyres, S. W.; Knoll, A. H. (2005). "Sedimentary rocks at Meridiani Planum: Origin, diagenesis, and implications for life on Mars". Earth Planet. Sci. Lett. 240: 1–10. Bibcode:2005E&PSL.240....1S. doi:10.1016/j.epsl.2005.09.038.
  74. Squyres, S. W.; et al. (2006). "Two years at Meridiani Planum: Results from the Opportunity rover". Science. 313: 1403–1407. doi:10.1126/science.
  75. M. Wiseman, J. C. Andrews-Hanna, R. E. Arvidson3, J. F. Mustard, K. J. Zabrusky DISTRIBUTION OF HYDRATED SULFATES ACROSS ARABIA TERRA USING CRISM DATA: IMPLICATIONS FOR MARTIAN HYDROLOGY. 42nd Lunar and Planetary Science Conference (2011) 2133.pdf
  76. DiscoveryChannel.ca - Mars avalanche caught on camera
  77. Rincon, Paul (March 17, 2007). "'Cave entrances' spotted on Mars". BBC News.
  78. Shiga, David (August 2007). "Strange Martian feature not a 'bottomless' cave after all". New Scientist. Retrieved 2010-07-01.
  79. "Teen project one-ups NASA, finds hole in Mars cave". AFP. 2010-06-23. Retrieved 2010-07-01.
  80. Thompson, Andrea (2009-10-26). "Mars Caves Might Protect Microbes (or Astronauts)". Space.com. Retrieved 2010-07-01.
  81. "HiRISE | Inverted Channels North of Juventae Chasma (PSP_006770_1760)". Hirise.lpl.arizona.edu. Retrieved 2012-01-16.
  82. Newsom, Horton E.; Lanza, Nina L.; Ollila, Ann M.; Wiseman, Sandra M.; Roush, Ted L.; Marzo, Giuseppe A.; Tornabene, Livio L.; Okubo, Chris H.; et al. (2010). "Inverted channel deposits on the floor of Miyamoto crater, Mars". Icarus. 205 (1): 64–72. Bibcode:2010Icar..205...64N. doi:10.1016/j.icarus.2009.03.030.

Bibliography

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