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In the tectonic history of Mars, two primary tectonic events are usually considered. The first is the process that lowered and resurfaced the northern hemisphere, resulting in a planet whose crustal thickness is distinctly bimodal—this is referred to as the hemispheric dichotomy (Fig. 1). The second tectonic event is the process that formed the Tharsis rise, which is a massive volcanic province that has had major tectonic influences both on a regional and global scale. These events largely pertain to the three major physiographic provinces of Mars; the northern plains, the southern highlands, and the Tharsis plateau. The different geological and tectonic characteristics of these regions will be described in the following section. Hypotheses proposed to explain how the two primary tectonic events may have occurred are usually divided into endogenic and exogenic processes, both of which will be discussed in this article.
Contents
- The Southern Highlands
- The Northern Plains
- The Tharsis Plateau
- Hypsometry
- Endogenic origins
- Exogenic origins
- Tectonic implications of magnetic anomalies
- Mantle plume origin
- Dike intrusion origin
- Accretion of terranes
- Tectonic implications of Valles Marineris
- References
Possible tectonic implications of magnetic anomalies detected on Mars will also be discussed. These magnetic anomalies are linear in shape and of alternating polarity, much like those found on Earth that have been a product of seafloor spreading. A process akin to seafloor spreading has also been proposed to explain the magnetic anomalies on Mars, and will be discussed below.
Furthermore, recent research claims to have found the first strong evidence for plate tectonics on Mars. This discovery refers to a large-scale strike-slip fault zone in the Valles Marineris through system, which has been likened to transform faults on Earth such as the San Andreas and Dead Sea faults. This discovery could have major implications for our future understanding of Martian tectonics.
The Southern Highlands
The southern highlands are heavily cratered and separated from the northern plains by the global dichotomy boundary. Strong magnetic stripes with alternating polarity run roughly E-W in the southern hemisphere, concentric with the south pole. These magnetic anomalies are found in rocks dating from the first 500 million years in Mars’ history, indicating that an intrinsic magnetic field would have ceased to exist before the early Noachian. The magnetic anomalies on Mars measure 200 km width, roughly ten times wider than those found on Earth.
The Northern Plains
The northern plains are several kilometers lower in elevation than the southern highlands, and have a much lower crater density, indicating a younger surface age. The underlying crust is however thought to be the same age as that of the southern highlands. Unlike the southern highlands, magnetic anomalies in the northern plains are sparse and weak.
The Tharsis Plateau
The Tharsis plateau, which sits in the highland-lowland boundary, is an elevated region that covers roughly one quarter of the planet. Tharsis is topped by the largest shield volcanoes known in the solar system. Olympus Mons stands 24 km tall and is nearly 600 km in diameter. The adjoining Tharsis Montes consists of Ascraeus, Pavonis, and Arsia. Alba Mons, at the northern end of the Tharsis plateau, is 1500 km in diameter, and stands 6 km above the surrounding plains. In comparison, Mauna Loa is a meager 120 km wide and stands 9 km above the sea floor.
The load of Tharsis has had both regional and global influences. Extensional features radiating from Tharsis include grabens several kilometers wide, and hundreds of meters deep, as well as enormous troughs and rifts up to 600 km wide and several kilometers deep (Fig. 2). These grabens and rifts are bounded by steeply dipping normal faults, and can extend for distances up to 4000 km. Their relief indicates that they accommodate small amounts of extension on the order of 100 m or less. It has been argued that these grabens are surface expressions of deflated subsurface dikes.
Circumferential to Tharsis are so-called wrinkle ridges (Fig. 2). These are compressional structures composed of linear asymmetric ridges that can be tens of kilometers wide and hundreds of kilometers long. Many aspects of these ridges appear to be consistent with terrestrial compressional features that involve surface folding overlying blind thrust faults at depth. Wrinkle ridges are believed to accommodate small amounts of shortening on the order of 100 m or less. Larger ridges and scarps have also been identified on Mars. These features can be several kilometers high (as opposed to hundreds of meters high for wrinkle ridges), and are thought to represent large lithosphere-scale thrust faults. Displacement ratios for these are ten times those of wrinkle ridges, with shortening estimated to be hundreds of meters to kilometers.
Approximately half of the extensional features on Mars formed during the Noachian, and have changed very little since, indicating that tectonic activity peaked early on and decreased with time. Wrinkle ridge formation both around Tharsis and in the eastern hemisphere is thought to have peaked in the Hesperian, likely due to global contraction attributed to cooling of the planet.
Hypsometry
Gravity and topography data show that crustal thickness on Mars is resolved into two major peaks, with modal thicknesses of 32 km and 58 km in the northern and southern hemispheres, respectively (Fig. 3). Regionally, the thickest crust is associated with the Tharsis plateau, where crustal thickness in some areas exceeds 80 km, and the thinnest crust with impact basins. The major impact basins collectively make up a small histogram peak from 5 to 20 km.
The origin of the hemispheric dichotomy, which separates the northern plains from the southern highlands, has been subject to much debate (Fig. 1). Important observations to take into account when considering its origin include the following: (1) The northern plains and southern highlands have distinct thicknesses, (2) the crust underlying the northern plains is essentially the same age as the crust of the southern highlands, and (3) the northern plains, unlike the southern highlands, contain sparse and weak magnetic anomalies. As will be discussed below, hypotheses for the formation of the dichotomy can largely be divided into endogenic and exogenic processes.
Endogenic origins
Endogenic hypotheses include the possibility of a very early plate tectonic phase. Such a scenario suggests that the northern hemispheric crust is a relic oceanic plate. In the preferred reconstruction, a spreading center extended north of Cimmeria Terra between Daedalia Planum and Isidis Planitia (Fig. 4). As spreading progressed, the Boreal plate broke into the Acidalia plate with south-dipping subducting beneath Arabia Terra, and the Ulysses plate with east-dipping subducting beneath Tempe Terra and Tharsis Montes. According to this reconstruction, the northern plains would have been generated by a single spreading ride, with Tharsis Montes qualifying as an island arc. However, subsequent investigations of this model show a general lack of evidence for tectonism and volcanism in areas where such activity was initially predicted.
Another endogenic process used to explain the hemispheric dichotomy is that of primary crustal fractionation. This process would have been associated with the formation of the Martian core, which took place immediately after planetary accretion. Nevertheless, such an early origin of the hemispheric dichotomy is challenged by the fact that only minor magnetic anomalies have been detected in the northern plains.
Single plume mantle convection has also been invoked to explain the hemispheric dichotomy (Fig. 5). This process would have caused substantial melting and crustal production above a single rising mantle plume in the southern hemisphere, resulting in a thickened crust. It has also been suggested that the formation of a highly viscous melt layer beneath the thickened crust in the southern hemisphere could lead to lithospheric rotation. This may have resulted in the migration of volcanically active areas toward the dichotomy boundary, and the subsequent placement and formation of the Tharsis plateau. The single plume hypothesis is also used to explain the presence of magnetic anomalies in the southern hemisphere, and the lack thereof in the northern hemisphere.
Exogenic origins
Exogenic hypotheses involve one or more large impacts as being responsible for the lowering of the northern plains. Although a multiple-impact origin has been proposed, it would have required an improbable preferential bombardment of the northern hemisphere. It is also unlikely that multiple impacts would have been able to strip ejecta from the northern hemisphere, and uniformly strip the crust to a relatively consistent depth of 3 km.
Mapping of the northern plains and the dichotomy boundary shows that the crustal dichotomy is elliptical in shape. This suggests that formation of the northern plains was caused by a single oblique mega-impact. This hypothesis is in agreement with numerical models of impacts in the 30-60° range, which are shown to produce elliptical boundary basins similar to the structure identified on Mars. Demagnetization resulting from the high heat associated with such an impact can also serve to explain the apparent lack of magnetic anomalies in the northern plains. It also explains the younger surface age of the northern plains, as determined by significantly lesser crater density. Overall, this hypothesis appears to fare better than others that have been proposed.
Tectonic implications of magnetic anomalies
The southern highlands display zones of intense crustal magnetization (Fig. 6). The magnetic anomalies are weak or devoid in the vicinity of large impact basins, the northern plains, and in volcanic regions, indicating that magnetization in these areas have been erased by thermal events. The presence of magnetic anomalies on Mars suggests that the planet maintained an intrinsic magnetic field early on in its history. The anomalies are linear in shape and of alternating polarity, implying a sequence of reversals and a process akin to seafloor spreading. The stripes are ten times wider than those found on Earth, indicating faster spreading or slower reversal rates. Although no spreading center has been identified, a map of the magnetic anomalies on Mars reveals that the lineations are concentric to the south pole.
Mantle plume origin
A process similar to seafloor spreading has been proposed to explain the presence of the concentric stripes around the Martian south pole. The process is that of a single large mantle plume rising in one hemisphere and downwelling in the opposite hemisphere (Fig. 4). In such a process, new crust produced would be emplaced in concentric circles spreading radially from a single upwelling point, consistent with the pattern observed on Mars. This process has also been invoked to help explain the Martian hemispheric dichotomy.
Dike intrusion origin
An alternative hypothesis claims that the magnetic anomalies on Mars are the result of successive dike intrusions due to lithospheric extension. As each dike intrusion cools, it would acquire thermoremanent magnetization from the planet’s magnetic field. Successive dikes would be magnetized in the same direction, until the magnetic field reverses its polarity, resulting in the subsequent intrusions recording the opposite direction. These periodic reversals would require that the dike intrusions migrate over time.
Accretion of terranes
Another study assumes a process of crustal convergence instead of generation, arguing that the magnetic lineations on Mars formed at a convergent plate margin through collision and accretion of terranes. This hypothesis suggests that the magnetic lineations on Mars are analogous to the banded magnetic anomalies in the North American Cordillera on Earth. These terrestrial anomalies are of similar geometry and size as those detected on Mars, with widths of 100–200 km.
Tectonic implications of Valles Marineris
Recent research claims to have found the first strong evidence for plate tectonic on Mars. The discovery refers to a large-scale (>2000 km in length and >150 km in slip) and quite narrow (<50 km wide) strike-slip fault zone in the Valles Marineris trough system, referred to as the Ius-Melas-Coprates fault zone (Fig. 7). The Valles Marineris trough system, which is over 4000 km long, 600 km wide, and up to 7 km deep, would, if located on Earth, extend all the way across North America.
The study indicates that the Ius-Melas-Coprates fault zone is a left-slip transtensional system similar to that of the Dead Sea fault zone on Earth. The magnitude of displacement across the fault zone is estimated to be 150–160 km, as indicated by the offset rim of an old impact basin (Fig. 7). If normalizing the magnitude of the slip to the surface area of the planet, the Ius-Melas-Coprates fault zone has a displacement value significantly larger than that of the Dead Sea fault, and slightly larger than that of the San Andreas fault. The lack of significant deformation on both sides of the Ius-Melas-Coprates fault zone over a distance of 500 km suggests that the regions bounded by the fault behave as rigid blocks. This evidence essentially points to a large strike-slip system at a plate boundary, in terrestrial terms known as a transform fault.