User:Awebb6/sandbox/Surface features of Venus

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Radar global map of the surface of Venus.

The surface of Venus is dominated by well-preserved geologic features that include volcanism, large meteorite impacts, and aeolian sedimentation. Venus has a unique surface geology due to its single, strong crustal plate, which creates a unimodal elevation distribution (over 90% of the surface lies withing an elevation of -1.0 and 2.5 km)[1] that preserves geologic structures for long periods of time. Studies of the Venusian surface are based on imaging, radar, and altimetry data collected from several exploratory space probe missions, particularly the Magellan probe since 1961 (see Venus Exploration). Despite its similarities to Earth in size, mass, density, and possibly composition, Venus has a unique geology that is unlike Earth. The surface of Venus is relatively young compared to other terrestrial planets (<500 million years), which could represent a global-scale resurfacing event happened at about that time that buried much of the previous rock record.[2] Venus is believed to have approximately the same bulk element composition as Earth, due to similarities in densities and size, but the exact composition is unknown. The surface conditions on Venus are also more extreme than Earth, with temperatures ranging from 453-473° C and pressures of 95 bar.[3] Venus also contains no water, so the crustal rock is extremely strong and surface features are well preserved. Surface features seen on Venus give evidence to the planetary processes at work, and twenty features have been named thus far. These features include local features, such as craters, coronae, and undae, as well as regional-scale features, such as planitiae, plana, and tesserae.[4]

Plains[edit]

Plains are large areas of relatively flat topography on Venus that form at varying elevations. Plains with elevations withing 1-3 km of the datum are referred to as lowland plans, or planitiae, and those above are named highland plains, or plana[4]. Plains cover 80% of the Venusian surface, and, unlike those seen on other silicate planets, are heavily faulted or fractured throughout. Structurally, these plains contain features such as wrinkle ridges, grabens (fossa and linea), fractures, scarps (rupes), troughs, hills (collis), and dikes in both local and region scales[5]. Plains often contain visible flow patterns, indicating a source from volcanic lava flows. The more pronounced lave flow fields are named fluctūs. The presence of surface flow patterns, in conjunction with crosscutting valleys, has lead to the leading hypothesis that these plains likely formed by global lava flows over a short timescale and were subsequently exposed to compressional and extensional stresses.[6] Structurally, plains are often deformed in belts of ridges (dorsa) or fractures (lineae) of various orientation and morphology.

Channels/Valles[edit]

Baltis Vallis A radar mosaic from Magellan showing a 600 km long segment of Baltis Vallis, a channel system on Venus that is longer than the Nile.

The surface of Venus contains over 200 channel systems, named valles, that resemble terrestrial rivers. These channels vary in length and width and are commonly found in planar regions of the planet. Channel length and width ranges from the minimum resolution of Magellan imaging to over 6800 km long (Baltis Vallis) and up to 30 km wide. There global distribution is not uniform, and tend to concentrate around the equatorial region, near volcanic structures. Venusian valles also show characteristics of flows, such as levees on the margins and downstream narrowing and shallowing. Channels also do not contain tributaries, despite their large scale. However, because of the high surface temperature of Venus, liquid water is unstable, making their comparison with terrestrial rivers difficult. These features are similar to lava flows on other terrestrial planets, which has lead to the conclusion that these valleys likely formed from volcanic flows. This is also suggested by the evidence of cooled lava flows filling the valles. [7] Channels likely formed in very short timescales (1-100 years), indicating very fast movement and erosion of lavas.[6] Venusian channels are classified by morphology and include three types: simple, complex, and compound.[8]

  • Simple Channels are single channel valleys with little to no branching or anastomosing. Types of simple channels observed on Venus include sinuous rilles, simple channels with flow margins, and canali. Sinuous rilles are like those seen on the Moon; narrow erosive channels that originate from regions of volcanic collapse, such as coronae. Simple channels with flow margin are located in obvious flow fields, have an undefined source and end, and are believed to feed into large flows from surrounding volcanics. Canali, like the Baltis Vallis, are long flows with constant width and depth that may contain abandoned channels, bends, and levees, indicating they are sourced from large amounts of thick lavas.[7][8]
  • Complex Channels are channels that can be braided, anastomosing, or in distributary patterns. They commonly form on lava flow deposits, but also occur elsewhere. Complex channels without flow margins may form part of a larger flow system, and form as channels of lava flows erode into the crust. Complex channels with flow margins appear as non-erosional, and their individual channels are separated by islands of crust of differing radar qualities.[7][8]
  • Compound Channels show simple and complex channel structures. These channels usually begin as simple channels and bifurcate and meander as flow energy decreases on its distal reaches.[7][8]

Volcanism[edit]

Volcanic Centers[edit]

Maat Mons with a vertical exaggeration of 22.5. Maat Mons is the second highest mountain on Venus, and is a recently active shield volcano.

Over 1100 volcanic structures over 20 km in diameter have been identified on Venus, and it is assumed that smaller structures probably number many times these. These structures include large volcanic edifices, shield volcano fields, and individual calderas. Each of these structures represents a center of extrusive magma eruption and differences in amount of magma released, depth of the magma chamber, and rate of magma replenishment effect volcano morphology. When compared to Earth, the number of preserved volcanic zones is staggering, and this is based on Venus' strong crust due to a lack of water. Volcanic centers on Venus are not distributed evenly, as over half of the centers are found in and around the Beta-Atla-Themis region, which covers <30% of the planet's surface. These tend to occur in mid to upper altitudes, where rifting and extension are common, and they signal mantle upwellings to the surface.[9] Volcanic centers on Venus are characterized in two main categories based on the ability or inability to create a shallow magma reservoir: Large flows originating from a single edifice or extensive regions with many small eruption sites clustered together.[10]

  • Single Volcanoes are thus named for a single, large edifice. Volcanoes of this type include large volcanoes (>100 km in diameter, often named mons, examples: Theia Mons and Maat Mons), intermediate volcanoes (20-100 km in diameter), and calderas. These single eruption center volcanoes are sustained by a shallow magma chamber in the crust. The magma chamber is replenished by magma from mantle upwelling and decompression melting, causing pooling and trapping of a reservoir. The trapping of a magma chamber allows long term eruption and results in magma flows that may create large volcanic domes and flow deposits. The extrusion of magma to the surface is often linked to rifting or extensional tectonics in the region, and the shape of the dome or magma flow field is determined by the chemistry and viscosity of the magma. Each of these types of volcanoes can further be described based on the shape of the dome created, number of edifices present, presence of rifting along the dome, radial fracturing, or collapse of the magma chamber. Intermediate volcanoes with domical surface cones are named tholus, and pancake-shaped volcanoes are named farrum.[4] Calderas are circular depressions on the surface believed to have formed by deformation above a cooling magma chamber. Calderas on Venus are characterized as simple, single depressions, called coronae, and complex, radially fractured zones, called arachnoids. Some caldera are named patera.[10]
  • Shield Field are regions 100-200 km in diameter that contain many small, mostly shield, volcanoes (<20 km). Such fields may have tens to hundreds of shield volcanoes. Rarely, individual shield volcanoes will be named colles.[4] These fields form in areas where the magma replenishment rate is too low to produce a magma reservoir in the crust, resulting in several small eruptions on a regional scale. The dominance of shield-type volcanoes in these regions has lead the name shield fields.[10]

Coronae[edit]

Coronae are large, circular structures with concentric fractures around them that result from mantle upwelling followed by extensional collapse. Since many sequences of upwelling and collapse have been observed as structurally different coronae on Venus' surface, all coronae appear to share a sequence of heavy volcanism due to upwelling, topographic rise, tectonic deformation, subsidence due to gravitational collapse, and continued volcanism. Coronae on Venus differ in the location of topographic uplift, and have been characterized as such. Topographic uplift may occur in the depression, the rim, the outer rim, or a combination of these locations. A collapsing coronae coupled with extensional stressing may result in rifting, creating a chasmata region.[11][9]

Large Lava Flow Fields[edit]

Large lava flow fields are described as flood-type lava that can be seen in fluctus fields. These are regions flooded with many low-viscosity volcanic flows from a single source that covers the area in a continuous flow field. Some flows may be radially distributed around a volcano of coronae as an apron, be fan-shaped, or sub-parallel in their orientation. Large flow fields may be sourced from large volcanoes, calderas, rift structures, or shield volcano fields and they are often associated with extensional environments.[10][9]

Topographic Rises[edit]

Topographic rises are domal-shaped areas of high topography that result from both volcanic and tectonic processes. These areas range from 1-4 km above the datum and 1000-3000 km across. [9][10] These rises are associated with high density anomalies, which indicates a source from mantle plumes beneath the crust that warp and uplift the region. Of the topographic rises on Venus, three types have been identified based on their dominating tectonic or volcanic morphology: volcano dominated, rift dominated, and corona dominated. Volcano dominated, such as the Bell Regio, rises have volcanoes atop the topographic rise. Rift dominated rises are uplifted by rifting and thinning of the lithosphere and include the Beta Regio and the overlying Theia Mons. In a coronae dominated rise, uplift is caused by the gravitational collapse and extenstion of a magma chamber and include the Themis Regio.[9]

Tesserae[edit]

Tesserae are a feature unique to Venus and are characterized as continent-sized regions of high topography (1 to >5 km above the datum) that are heavily deformed, often with complex patterns of ridges. These areas are formed by the intersection of at least two structural components. Tesserae are classified base on their structural components.Types of Tesserae[12] Examples include the Ishtar Terra and the Aphrodite Terra. Tesserae are considered to be the oldest surface features on Venus because of their extensive deformation, and, if true, may represent conditions on Venus before a global resurfacing event.[12] Some of the ridges found on tesserae terrains, particularly in the Ishtar Terra, form large mountain (or Mons) belts. Along the equatorial and southern latitudes, tesserae are labeled regiones, while those northern latitudes are labeled tessera.[4]

Impact Craters[edit]

Impact craters on the surface of Venus (image reconstructed from radar data)
Mechanism for meteor breakup. As an object enters the atmosphere, it weakens due to frictional heating and can fracture into smaller pieces.

Impact craters are roughly circular shaped depressions in the surface of a planet due to high velocity impacts with extraterrestrial bodies. The surface of Venus contains almost 1000 impact craters. However, unlike some planets in our system, Venus' thick atmosphere creates a strong shield that decelerates, flattens, and can fracture incoming projectiles. The Venusian surface is devoid of small craters (≤30-50 km in size) because of the effect the atmosphere has on small bodies. Depending on the angle of impact, velocity, size, and strength of the approaching body, the atmosphere may tear and crush the projectile, essentially melting it in the air. This is an important observation for studies of the surface of Venus, as crater are used to determine relative ages and to approximate absolute ages of surface features.[13]

Craters on Venus are kept in pristine condition, thus making their classification and impact mechanics easy to interpret. Small projectiles burn up in the atmosphere, and those that make it to the surface break into smaller pieces, creating clusters of impact craters similar in appearance to circular lunar craters. As crater size increases, the chance of breakup in the atmosphere decreases and the impact craters become more circular with central peaks from isostatic rebound of the crust. The atmosphere can flatten and slow larger meteoroids to terminal velocity and cause them to explode on impact or near the surface, showering the region in debris. The shockwave from these explosions can flatten the surrounding area for several kilometers. Large impacts create parabolic excavation cones and flows of lava-like debris.[14]

Aeolian structures[edit]

An example of a yardang near Meadow, Texas (USDA photo).

Recent Magellan images show over 6000 aeolian landforms, including dunes (or undae), wind streaks, and yardangs. Undae and yardangs have direct analogues on Earth and the process that creates can be directly applied to those seen on Venus. Large dune fields have been identified on the surface and they range in size from meters to hundreds of meters. Similarly, yardang fields may exist in locations such as the Mead crater.[4] Wind streaks are parallel linear streaks that form as prevailing winds erode the surface geology. These features are important because the illustrate the erosive effect the atmosphere has on the surface of Venus.[15]

See Also[edit]

Venus

Geology of Venus

Planetary nomenclature

List of geological features on Venus

List of coronae on Venus

List of craters on Venus

List of extraterrestrial dune fields

List of montes on Venus

List of terrae on Venus

References[edit]

  1. ^ Ford, P.G.; Pettengill, G.H. (Aug 25, 1992). "Venus topography and kilometer-scale slopes". Journal of Geophysical Research: Planets. 97 (E8): 13103–13114. doi:10.1029/92JE01085. {{cite journal}}: |access-date= requires |url= (help)
  2. ^ Basilevsky, A.T.; Head, J.W.; Schaber, G.G.; Strom, R.G. (1997). The resurfacing history of Venus (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 1047–1084. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)
  3. ^ Taylor, S.R.; McLennan, S.M (2010). Planetary Crusts: Their composition, origin, and evolution. The Cambridge University Press. pp. 181–206. ISBN 9780521841863. {{cite book}}: |access-date= requires |url= (help)
  4. ^ a b c d e f Tanaka, K.L.; Senske, D.A.; Price, M.; Kirk, R.L. (1997). "Physiography, geomorphic/geologic mapping, and stratigraphy of Venus" (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 667–694. ISBN 0816518300.
  5. ^ Banerdt, W.B.; McGill, G.E.; Zuber, M.T. (1997). Plains Tectonics on Venus (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 901–930. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)
  6. ^ a b Basilevsky, A.T.; Head, J.W. (June 1, 1996). "Evidence for rapid and widespread emplacement of volcanic plains on Venus: Stratigraphic studies in the Baltis Vallis region". Geophysical Research Letters. 23 (12): 1497–1500. doi:10.1029/96GL00975. {{cite journal}}: |access-date= requires |url= (help)
  7. ^ a b c d Baker, V.R.; Komatsu, G.; Parker, T.J.; Gulick, V.C.; Kargel, J.S.; Lewis, J.S. (Aug 25, 1992). "Channels and Valleys on Venus: Preliminary Analysis of Magellan Data". Journal of Geophysical Research. 97 (E8): 13, 421–13, 444. doi:10.1029/92JE00927. {{cite journal}}: |access-date= requires |url= (help)
  8. ^ a b c d Baker, V.R.; Komatsu, G.; Gulick, V.C.; Parker, T.M. (1997). Channels and Valleys (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 757–793. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)
  9. ^ a b c d e Stofan, E.R.; Smrekar, S.E. (2005). "Large topographic rises, coronae, large flow fields, and large volcanoes on Venus: Evidence for mantle plumes?". Geologic Society of America Special Paper. 388: 841–861. doi:10.1130/2005.2388(47). {{cite journal}}: |access-date= requires |url= (help)
  10. ^ a b c d e Crumpler, L.S.; Aubele, J.C.; Senske, D.A.; Keddie, S.T.; Magee, K.P.; Head, J.W. (1997). Volcanoes and centers of volcanism on Venus (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 697–756. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)
  11. ^ Stofan, E.R.; Hamilton, V.E.; Janes, D.M; Smrekar, S.E. (1997). Coronae on Venus: Morphology and origin (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 931–965. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)
  12. ^ a b Hansen, V.L.; Willis, J.J.; Banerdt, W.B. (1997). "Tectonic overview and synthesis" (in Venus II, eds. Bougher, S.W.). The University of Arizona Press. pp. 797–844. ISBN 0816518300.
  13. ^ McKinnon, W.B.; Zahnle, K.J.; Ivanov, B.A.; Melosh, H.J. (1997). Cratering on Venus: Models and observations (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 969–1014. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)
  14. ^ Herrick, R.R.; Sharpton, V.L.; Malin, M.C.; Lyons, S.N.; Feely, K. (1997). Morphology and morphometry of impact craters (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 1015–1046. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)
  15. ^ Greenley, R.; Bender, K.C.; Saunders, R.S.; Schubert, G.; Weitz, C.M. (1997). Aeolian processes and features on Venus (in Venus II, eds. Bougher, S.W. et al.). The University of Arizona Press. pp. 547–589. ISBN 0816518300. {{cite book}}: |access-date= requires |url= (help)

Link[edit]

Surface features of Venus

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