Derivation of primary magmas and melting of crustal materials on Venus: Some preliminary petrogenetic considerations

Hess, P. C.; Head, J. W.

doi:10.1007/bf00142389

Cited by 52 publications

(35 citation statements)

References 66 publications

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“…Whether melting or density inversion occurs is dependent on the conductive geotherm (Anderson, 1980;Hess and Head, 1989,199Ob). For a conductive geotherm of 25"C/km, the basalt liquidus is crossed at about 40 km depth (Figure lc) (Hess and Head, 1990b). If a thickness of crust equivalent to this depth was produced over the history of the planet, then the crustal production rate would be 4.1 km3/yr and the thickness production rate would be about 8.9 km/b.y.…”

Section: B Crustal Thickening Processesmentioning

confidence: 99%

Processes of crustal formation and evolution on Venus: An analysis of topography, hypsometry, and crustal thickness variations

Head

1990

Earth Moon Planet

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On Venus, present evidence indicates a crust of predominantly basaltic composition and a relatively young average age for the surface (several hundreds of millions of years). Estimates of crustal thickness from several approaches suggest an average crustal thickness of lo-20 km for much of the lowlands and rolling plains and a total volume of crust of about 1 x 10" km3, approximately comparable to the present crustal volume of the Earth (1.02 x 10" km3). The Earth's oceanic crust is thought to have been recycled at least lo-20 times over Earth history. The near-coincidence in present crustal volumes for the Earth and Venus suggests that either: (1) the presently observed crust of Venus represents the total volume that has accumulated over the history of the planet and that crustal production rates are thus very low, or (2) that crustal production rates are higher and that there is a large volume of "missing crust" unaccounted for on Venus which may have been lost by processes of crustal recycling.Known processes of crustal formation and thickening (impact-related magma ocean, vertical differentiation, and crustal spreading) are reviewed and are used as a guide to assess regional geologic evidence for the importance of these processes on Venus. Geologic evidence for variations in crustal thickness on Venus (range and frequency distribution of topography, regional slopes, etc.) are outlined. The hypothesis that the topography of Venus could result solely from crustal thickness variations is assessed and tested as an end-member hypothesis. A map of crustal thickness distribution is compiled on the basis of a simple model of Airy isostasy and global Venus topography. An assessment is then made of the significance of crustal thickness variations in explaining the topography of Venus. It is found that the distinctive unimodal hypsometric curve could be explained by: (1) a crust of relatively uniform thickness (most likely lo-20 km thick) comprising over 75% of the surface, (2) local plateaus (tessera) of thickened crust (about 20-30 km) forming less than 15% of the surface, (3) regions of apparent crustal thicknesses of 30-50 km (Beta, Ovda, Thetis, Atla Regiones and Western Ishtar Terra) forming less than 10% of the surface and showing some geologic evidence of crustal thickening processes (these areas can be explained on the basis of geologic observations and gravity data as combinations of thermal effects and crustal thickening), and (4) areas in which Airy isostasy predicts crustal thicknesses in excess of 50 km (the linear erogenic belts of Western Ishtar Terra, less than 1% of the surface).It is concluded that Venus hypsometry can be reasonably explained by a global crust of generally similar thickness with variations in topography being related to (1) crustal thickening processes (orogenic belts and plateau formation) and (2) local variations in the thermal structure (spatially varying thermal expansion in response to spatially varying heat flow). The most likely candidates for the formation and evolution of the...

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Section: B Crustal Thickening Processesmentioning

confidence: 99%

Processes of crustal formation and evolution on Venus: An analysis of topography, hypsometry, and crustal thickness variations

Head

1990

Earth Moon Planet

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“…GRS-measured K, U, and Th Figure 1 Calculations of partitioning during partial melting were made using the mass balance The K-U-Th pattern for partial melts could be influenced by volatile components such as H20 and CO2. However, an attempt to allow for the role of volatiles in Venus petrogenesis would raise more questions than it answered because the abundances of volatile species in the Venus interior are poorly constrained (see Hess and Head [1990] for a summary), and necessary data on (low-density fluid)/melt, fluid/mineral partition coefficients, particularly for accessory minerals and for a range of fluid compositions, are among the suggestions for future work made by Green [1994] in his recent review. …”

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confidence: 99%

Geochemical constraints on petrogenic processes on Venus

Николаева¹,

Ariskin²

1999

J. Geophys. Res.

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“…Hess and Head (1989) demonstrated on a theoretical basis that no magma type may be arbitrarily excluded from consideration for Venus. The greatest difference between magma types on Venus and Earth may occur at convergent zones, such as proposed for Ishtar Terra, due to the suspected lack of water in the Venusian crust.…”

Section: Eruption Stylesmentioning

confidence: 99%

Lakshmi Planum, Venus: Characteristics and models of origin

Roberts

Head

1990

Earth Moon Planet

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Lakshmi Planum is distinctive and unique on the surface of Venus as an expansive (-2 x lo6 km2), relatively smooth, flat plateau containing two large shield volcanoes and abundant volcanic plains in the midst of a region of extreme relief. It rises 3-5 km above the datum and is surrounded on all sides by bands of mountains interpreted to be of compressional tectonic origin. The major units mapped on Lakshmi are volcanic edifices, smooth, ridged and grooved plains units, and structural units referred to as ridged terrain. Three styles of volcanism are observed to dominate the surface of Lakshmi. Distributed effusive volcanism is associated with extensive plains deposits and many of the small shields, domes and cones mapped within the plateau. Centralized effusive volcanism is primarily associated with the paterae, Colette and Sacajawea, and their circumferential low-shieldforming deposits. The precise origin and evolution of these unusually large and complex structures is not understood, although a catastrophic, explosive origin is unlikely. Pyroclastic volcanism may be represented by a unit referred to as the "diffuse halo". The origin and evolution of Lakshmi Planum is closely related to its compressional tectonic environment; volcanism on Lakshmi has occurred synchronously with tectonism in the surrounding erogenic belts. A model for the origin and evolution of Lakshmi Planum consisting of a continuous sequence of convergence and horizontal shortening of crustal segments against a preexisting block of tessera seems best able to account for the elevation, plateau shape and irregular polygonal outline of Lakshmi, as well as the presence of ridged terrain and its resemblance to tessera. Volcanism on Lakshmi is proposed to be the result of basal melting of a thickened crustal root. According to this model, the origin and evolution of Lakshmi Planum has consisted of the following sequence of events: (1) formation of a large, elevated block of tessera surrounded by low-lying plains; (2) convergence and underthrusting of crustal segments to produce peripheral mountain ranges, thickening, and uplift of the plateau; and (3) basal melting of the thickened crust and underthrust material and surface volcanism that occurred synchronously with continued edge deformation.

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Derivation of primary magmas and melting of crustal materials on Venus: Some preliminary petrogenetic considerations

Cited by 52 publications

References 66 publications

Processes of crustal formation and evolution on Venus: An analysis of topography, hypsometry, and crustal thickness variations

Processes of crustal formation and evolution on Venus: An analysis of topography, hypsometry, and crustal thickness variations

Geochemical constraints on petrogenic processes on Venus

Lakshmi Planum, Venus: Characteristics and models of origin

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