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This 3D view depicts the border between the lowland plains on the right and the crustal plateau region of Ovda Regio on the left. This image was created using Magellan's data and organized by color with emissivity. Image courtesy of NASA Jet Propulsion Laboratory

Ovda Regio is a Venusian crustal plateau located near the equator in the western highland region of Aphrodite Terra and stretches from 10^oN to 15^oS and 50^oE to 110^oE. Known as the largest crustal plateau in Venus, the Regio covers an area of approximately 15,000,000 km² and bounded by regional plains to the north, the Salus Tessera to the west, the Thetis Regio to the east, and Kuanja as well as Ix Chel chasmata to the south. The crustal plateau serves as a place to hold the localized tessera terrains in the planet, which makes up roughly 8% of Venus' surface area. ^[1][2]The tectonic evolution of crustal plateaus on Venus has been a highly debated topic in the planetary science community. It is believed that understanding its complex evolution will unlock the keys to the fundamental knowledge of geodynamic history of Venus.

Structural Geology

Extensive research has been conducted to describe the structural geology of Ovda Regio. Synthetic aperture radar (SAR) images from the NASA Magellan mission has been continuously analyzed to recognize the distribution of its structural features. The distribution was then mapped to find its temporal and spatial relation to find insight into the Regio's deformation and formation mechanisms. ^[1] The challenge in this process is to find the ideal temporal and spatial relationship, which holds prominent role in comprehending the tectonic processes. In terms of structural setting, the Regio is characterized mainly by ribbons, folds, and a complex of graben.

Western Ovda

Folds and a distinct compositional layering generally describe the western part of Ovda Regio. Compositional layering means that the structural layers are different in terms of its chemical composition. ^[3]Particularly, the layers are differentiated based on its tone and textural recognition from SAR images. The folds observed in this part of the Regio are concentric, associated with plunges, and share a common axis that is trending in a east-west fashion.^[4] Another feature that is observed in this part is ribbon structures. Ribbons can be described as structures that are steep with long depression of about 1-3 km in width and shallow depths of less than 500 m. ^[5][6] In contrast to the folding structures, the ribbons in the western part are randomly distributed. ^[4]

Central Ovda

The central Ovda is distinguishable by ridges exhibiting similar east-west fashion as in the western Ovda. These ridges are common on the northern margin and often share a common axis with the fold structures. Other structural features observed in this part of Ovda are imbricate stack and duplex formation on the southern margin. ^[4] A more detailed analysis was conducted in this part indicate that the central Ovda hosts a strike-slip tectonic regime where the deformation are accompanies by three different structures: folds, normal faults, and strike-slip faults.^[7]

Eastern Ovda

In the eastern part of Ovda, the structural setting is define mainly by wide folds and ribbons structures. The wide folds are observed to have amplitudes up to 25 km and several hundred km in length. While the ribbons structures holds generally a radial pattern. Some of the ribbon structures on this part of Ovda are quite difficult to interpret due to the SAR images' limited resolution. A good amount of graben are also present in this part, although the grabens are not highly distinguishable and are limited to fold crests.^[5]

Tectonic Evolution

There are a few ideas being continuously discussed in the planetary science community regarding the tectonic evolution of Ovda Regio:

 

The regional tectonic evolution at Ovda Regio. Modified from Chetty et al., 2010.^[4]

 

The tectonic evolution at the crustal plateau's margins of Ovda Regio. Modified from Romeo and Capote, 2010.^[8]

Regional Tectonic Evolution

Regionally, there are two separate phases of tectonic evolution. Initially, the Regio was at a stable state where there are no stresses acting on the crustal plateaus. This state was then followed by the first phase in which the north-south oriented compressional stresses act on the Regio and produced an east-west folding pattern. This pattern provides the primary structural framework in Ovda Regio. Then, the second phase took place in which the compressional stresses intensified and developed significant mega shear zones.^[4]

Marginal Tectonic Evolution

There are generally two different phases of structural evolution that describe the Regio's crustal plateau margins. The initial phase preceded the first phase and the last phase concluded the second phase. The initial phase was when all the material being set in place, which would then construct the tessera terrain. During the first phase, the thrust faults and fold belts started to develop parallel to the margins. At the beginning of the first phase, these faults and folds made an impact on the tessera terrain, but later on it made an impact on the intratessera volcanic plains. On second phase, all the thrust faults and fold belts experienced a perpendicular extension. Furthermore, the last phase occurred when the extensional events continuously carried out the deformed structures from the plateau and affecting the volcanic units.^[8]

Crustal Plateau Modelling

There are several models that have been debated for its precision in relation to crustal plateau formation in Venus, particularly in Ovda Regio:

The Downwelling Model

This model describes that the mantle downwelling flow assisted the development of crustal thickening and shortening of the ductile crust because of compression and accretion of thin lithosphere. However, this model needs a lot amount of time of crustal thickening (1-4 billion years). ^[9][10] There are also a few constraints for this model. The first one is that this model provides no explanation for the contractional structures and the second one is that the timing of the extensional structures does not correlate well with the known cross-cutting relationships.^[8]

The Upwelling Model

This second model describes that the mantle upwelling (plume) flow accommodated the formation of crustal thickening by magmatic underplating and volcanic activities associated with the thin lithosphere.^[8][11] Planetary scientists that supports this model identify two categories of extensional structures: a long-narrow graben or also known as ribbons and a wide spaced graben. The sequence of formation for these structures is still debatable. Some group of scientists believed that the ribbons were formed first, followed later on by the wide spaced graben. But there is also another group of scientists believed the reverse sequence. ^[1][8]

The Impact Model

Under this model, the crustal plateaus were formed by lava ponds from mantle melting due to meteor impacts to the planet's thin lithosphere. Based on this model, the crustal plateaus would be uplifted by isostasy because the mantle underneath the lava ponds are depleted with residual melts as compared to the neighboring undepleted mantle.^[8][12] However, there are a few issues accompanying this model. The first issue is that scientists are not confidence that meteor impacts have the capabilities to melt a significant portion of the planet's lithosphere and generate enough magma that would cause isostasy. ^[13] The second issue is the planet's large folds need a lot amount of stresses to pass the thin brittle layer, but the underlying magma is not capable to transfer enough stresses through the layer.

References

1. Ghent, Rebecca; Hansen, Vicki (6 January 1999). "Structural and Kinematic Analysis of Eastern Ovda Regio, Venus: Implications for Crustal Plateau Formation". Icarus (139): 116–136. Retrieved 13 February 2015.
2. Kucinskas, Algis B.; Turcotte, Donald L.; Huang, Jie; Ford, Peter G. (25 August 1992). "Fractal Analysis of Venus Topography in Tinatin Planitia and Ovda Regio". Journal of Geophysical Research. 97 (E8): 13635–13641. Retrieved 13 February 2015.
3. Kroeger, Glenn C. "Exploring Earth". Trinity University. Retrieved 1 March 2015.
4. Chetty, T.R.K.; Venkatrayudu, M.; Venkatasivappa, V. (24 May 2010). "Structural Architecture and a New Tectonic Perspective of Ovda Regio, Venus". Planetary and Space Science (58): 1286–1297. Retrieved 13 February 2015.
5. Ghent, R.R.; Hansen, V.L. "Structural Analysis of Central and Eastern Ovda Regio, Venus" (PDF). Lunar and Planetary Institute. Lunar and Planetary Science XXVII. Retrieved 13 February 2015.
6. Hansen, Vicki L.; Willis, James J. (April 1998). "Ribbon Terrain Formation, Southwestern Fortuna Tessera, Venus: Implications for Lithosphere Evolution". Icarus. 132 (2): 321–343. Retrieved 29 March 2015.
7. Romeo, Ignacio; Capote, Ramon; Anguita, Francisco (10 February 2005). "Tectonic and kinematic study of a strike-slip zone along the southern margin of Central Ovda Regio, Venus: Geodynamical implications for crustal plateaux formation and evolution". Icarus. 175: 320–334. Retrieved 13 February 2015.
8. Romeo, I.; Capote, R. (13 June 2011). "Tectonic evolution of Ovda Regio: An example of highly deformed continental crust on Venus?". Planetary and Space Science (59): 1428–1445. Retrieved 13 February 2015.
9. Kidder, J.G.; Phillips, R.J. (1996). "Convection-driven subsolidus crustal thickening on Venus". Journal of Geophysical Research: 23181–23294. Retrieved 1 March 2015.
10. Bindschadler, Duane L.; Schubert, Gerald; Kaula, William M. (25 August 1992). "Coldspots and hotspots: Global tectonics and mantle dynamics of Venus". Geophysical Research: Planets. 97 (E8): 13, 495–13, 532. Retrieved 29 March 2015.
11. Hansen, Vicki L.; Phillips, Roger J.; Willis, James J.; Ghent, Rebecca R. (25 February 2000). "Structures in tessera terrain, Venus: Issues and answers". Geophysical Research. 105 (E2): 4135–4152. Retrieved 29 March 2015.
12. Hansen, Vicki L. (22 November 2006). "Geologic constraints on crustal plateau surface theories, Venus: the lava pond and bolide impact hypothesis" (PDF). Geophysical Research. 111. Retrieved 29 March 2015.
13. Ivanov, M.A.; Head, H.J. (2003). "Impacts do not initiate volcanic eruptions: Eruptions close to the crater" (PDF). Geology (31): 869–872. Retrieved 1 March 2015.