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

Romeo, I.; Capote, Ramón; Anguita, Francisco

doi:10.1016/j.icarus.2004.11.007

Cited by 34 publications

(29 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Koenig & Aydin (1998) and Fernàndez et al (2010) showed horse-tail terminations, en echelon folds, contractional bends and strike-slip offsets in Lavinia Planitia. Finally, Romeo et al (2005) and Chetty et al (2010) identified conjugate shear zones in Ovda Regio associated with tear-folds and imbricate duplexes. Continental drift may account for the substantial horizontal tectonism required by prominent strikeslip belts (Harris & Bédard 2014b).…”

Section: Tectonicsmentioning

confidence: 96%

“…However, the upwelling model cannot explain the widespread contractional tectonics observed at some plateau margins nor the complex compressional -extensional deformation recorded on crustal plateaux within so-called tesserae terrains (Ivanov & Head 1996;Gilmore et al 1998;Romeo et al 2005;Hansen & López 2010). On the other hand, the downwelling hypothesis fails to explain the flat-topped topography of plateaux, and, further, it requires an excessive amount of time for crustal thickening (Lenardic et al 1995;Kidder & Phillips 1996).…”

Section: Tectonicsmentioning

confidence: 99%

“…On a planet dominated by vertical tectonism and characterized by widely distributed deformations, there is no space for strikeslip shear belts that have traditionally been highly underconsidered on Venus (e.g. Solomon 1993;McGill et al 2010) despite the apparently straightforward evidence collected so far (Raitala 1994;Brown & Grimm 1995;Ansan et al 1996;Koenig & Aydin 1998;Tuckwell & Ghail 2003;Kumar 2005;Romeo et al 2005;Chetty et al 2010;Fernàndez et al 2010;Harris & Bédard 2014a, b). For example, Brown & Grimm (1995) highlighted en echelon fractures and folds along and within Artemis Chasma.…”

Section: Tectonicsmentioning

confidence: 99%

See 2 more Smart Citations

Volcanism and tectonism across the inner solar system: an overview

Platz

Byrne

Massironi

et al. 2014

View full text Add to dashboard Cite

Volcanism and tectonism are the dominant endogenic means by which planetary surfaces change. This book, in general, and this overview, in particular, aim to encompass the broad range in character of volcanism, tectonism, faulting and associated interactions observed on planetary bodies across the inner solar system -a region that includes Mercury, Venus, Earth, the Moon, Mars and asteroids. The diversity and breadth of landforms produced by volcanic and tectonic processes are enormous, and vary across the inventory of inner solar system bodies. As a result, the selection of prevailing landforms and their underlying formational processes that are described and highlighted in this review are but a primer to the expansive field of planetary volcanism and tectonism. In addition to this extended introductory contribution, this Special Publication features 21 dedicated research articles about volcanic and tectonic processes manifest across the inner solar system. Those articles are summarized at the end of this review.

show abstract

Section: Tectonicsmentioning

confidence: 96%

Section: Tectonicsmentioning

confidence: 99%

Section: Tectonicsmentioning

confidence: 99%

See 1 more Smart Citation

Volcanism and tectonism across the inner solar system: an overview

Platz

Byrne

Massironi

et al. 2014

View full text Add to dashboard Cite

show abstract

“…This interpretation is based on the assumption that the wavelength of each of these types of structures is indicative of the thickness of the brittle crust, being generated with a brittle-ductile transition deepened with time during the cooling of the plateau. However, Gilmore et al (1997Gilmore et al ( , 1998 and Romeo et al (2005) concluded that the deformation phases are first compressional and finally extensional. In this interpretation the extensional structures, including the long-narrow grabens, postdate or are contemporary with the generation of the compres sional structures.…”

Section: Introductionmentioning

confidence: 99%

“…On the one hand, the weak points of the downwelling model are: (1) a predicted domical shape instead of the flat-topped plateau geometry (Kidder and Phillips, 1996); (2) too much time is required for the thickening by crustal flow (1-4 billion years) (Kidder and Phillips, 1996). On the other hand, the main challenges of the plume hypothesis are: (1) there is no explanation for the extensive contractional tectonics observed (Ghent et al, 2005;Hansen, 2006); (2) the predicted timing of the extensional tectonics contradicts cross-cutting relationships in different locations (Gilmore et al, 1998;Romeo et al, 2005). Although Gilmore et al (1998) argued that the formation of ribbon-tessera terrain requires an excessive geothermal gradient, Ruiz (2007) indicated that the heat flow needed for generating ribbons is reasonable for a plume environment.…”

Section: Introductionmentioning

confidence: 99%

Pulsating continents on Venus: An explanation for crustal plateaus and tessera terrains

Romeo

Turcotte

2008

Earth and Planetary Science Letters

View full text Add to dashboard Cite

Geologic Map of Aphrodite Map Area (AMA; I-2476), Venus

Hansen

López

2020

Preprint

View full text Add to dashboard Cite

We present a 1:10-M-scale geologic map of the Aphrodite Map Area (AMA) of Venus (0°N-57°S/60-80°E). Geologic mapping employed NASA Magellan synthetic aperture radar and altimetry data. The AMA geologic map, with detailed structural elements and geologic units covering over one eighth of Venus' surface, affords an important and unique perspective to test models of global-scale geologic processes through time. Geologic relations record a history inconsistent with global catastrophic resurfacing. The AMA displays a regional coherence of preserved geologic patterns that record three sequential geologic eras: the ancient era, the Artemis superstructure era, and the youngest fracture zone era. The ancient era and Artemis superstructure, with a footprint covering more than 25% of the surface, are recorded in the Niobe Map Area to the north. The latter two eras likely overlap in time. The fracture zone domain, part of a globally extensive province, marks the most spatially focused tectonomagmatic domain within the AMA. Impact craters are both cut by and overprint fracture zone structures. Twelve percent of AMA impact craters that occur within the fracture zone domain predate or formed during fracture zone development. This observation indicates the relative youth of the fracture zone era and is consistent with the possibility that this domain remains geologically active. The AMA records a rich geologic history of large tract of the surface of Venus and provides an important framework to formulate new working hypotheses of Venus evolution and contribute to planning future studies of the surface of planets.

show abstract

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

Cited by 34 publications

References 26 publications

Volcanism and tectonism across the inner solar system: an overview

Volcanism and tectonism across the inner solar system: an overview

Pulsating continents on Venus: An explanation for crustal plateaus and tessera terrains

Geologic Map of Aphrodite Map Area (AMA; I-2476), Venus

Contact Info

Product

Resources

About