The influence of lithospheric flexure on magma ascent at large volcanoes on Venus

McGovern, P. J.; Rumpf, M.; Zimbelman, J. R.

doi:10.1002/2013je004455

Cited by 33 publications

(47 citation statements)

References 67 publications

(146 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…If many craters on Venus are volcanically modified, then the average surface age—at least of the uppermost few hundred meters—is quite young even with conventional assumptions about the impactor population (Herrick & Rumpf, ; O'Rourke et al, ). Given their abundant volcanic and tectonic signatures, above average heat flow locally at coronae is perhaps unsurprising in any case (e.g., McGovern & Solomon, ; McGovern et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…Lateral crustal flow and associated deformation then produces topographic features observed at coronae today. Similarly, McGovern et al () argued that loading of the lithosphere by large volcanoes could produce a subset of the features classified as coronae. In regions of low elastic thickness, control of magma ascent zones by lithospheric flexural stresses may produce annular ridges of volcanic material matching topographic signatures of some coronae.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Signatures of Lithospheric Flexure and Elevated Heat Flow in Stereo Topography at Coronae on Venus

O’Rourke

Smrekar

2018

JGR Planets

View full text Add to dashboard Cite

Signatures of lithospheric flexure were previously identified at a dozen or more large coronae on Venus. Thin plate models fit to topographic profiles return elastic parameters, allowing derivation of mechanical thickness and surface heat flows given an assumed yield strength envelope. However, the low resolution of altimetry data from the NASA Magellan mission has hindered studying the vast majority of coronae, particularly those less than a few hundred kilometers in diameter. Here we search for flexural signatures around 99 coronae over ∼20% of the surface in Magellan altimetry data and stereo‐derived topography that was recently assembled from synthetic aperture radar images. We derive elastic thicknesses of ∼2 to 30 km (mostly ∼5 to 15 km) with Cartesian and axisymmetric models at 19 coronae. We discuss the implications of low values that were also noted in earlier gravity studies. Most mechanical thicknesses are estimated as <19 km, corresponding to thermal gradients >24 K km−1. Implied surface heat flows >95 mW m−2—twice the global average in many thermal evolution models—imply that coronae are major contributors to the total heat budget or Venus is cooling faster than expected. Binomial statistics show that “Type 2” coronae with incomplete fracture annuli are significantly less likely to host flexural signatures than “Type 1” coronae with largely complete annuli. Stress calculations predict extensional faulting where nearly all profiles intersect concentric fractures. We failed to identify systematic variations in flexural parameters based on type, geologic setting, or morphologic class. Obtaining quality, high‐resolution topography from a planetwide survey is vital to verifying our conclusions.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Signatures of Lithospheric Flexure and Elevated Heat Flow in Stereo Topography at Coronae on Venus

O’Rourke

Smrekar

2018

JGR Planets

View full text Add to dashboard Cite

show abstract

“…Thus, these broad outlines of the geologic history of tectonism, together with the geological history of volcanism (Ivanov and Head, 2013) and the global geological map of Venus (Ivanov and Head, 2011), provide the basis to help distinguish among the range of proposed models for the geodynamic evolution of Venus (Shalygin et al, 2012;McGovern et al, 2013;Driscoll and Bercovici, 2014;Gillmann and Tackley, 2014;Taylor, 2014;Campbell et al, 2015).…”

Section: Summary/conclusionmentioning

confidence: 99%

The history of tectonism on Venus: A stratigraphic analysis

Иванов

Head

2015

Planetary and Space Science

View full text Add to dashboard Cite

“…The wall rocks are expected to have a Maxwellian viscoelastic rheology, and consequently, the maximum overpressure in the chamber will depend on buoyancy, recharge rates, chamber volume, and the temperature‐dependent wall rock viscosity [ Dragoni and Magnanensi , ; Jellinek and DePaolo , ; Karlstrom et al ., ; Karlstrom and Richards , ; Degruyter and Huber , ; Caricchi et al ., ]. Surface loading also modulates overpressure [ Pinel and Jaupart , ; Grosfils , ; McGovern et al ., ; de Silva and Gregg , ], and regional stresses and strain rates can influence magma ascent [e.g., Delaney et al ., ; Rubin , ; Buck et al ., ; Menand et al ., ; Daniels and Menand , ]. In the limit where viscous relaxation quickly alleviates lithospheric stresses from changes in magma volume or from loading and regional tectonics, buoyancy from volatile exsolution during decompression or second boiling controls eruptibility [ Tait et al ., ; Caricchi et al ., ; Malfait et al ., ; Degruyter and Huber , ].…”

Section: Introductionmentioning

confidence: 99%

The eruptibility of magmas at Tharsis and Syrtis Major on Mars

Black

Manga

2016

JGR Planets

View full text Add to dashboard Cite

Magnetic and geologic data indicate that the ratio of intrusive to extrusive magmatism (the I/E ratio) is higher in the Tharsis and Syrtis Major volcanic provinces on Mars relative to most volcanic centers on Earth. The fraction of magmas that erupt helps to determine the effects of magmatism on crustal structure and the flux of magmatic gases to the atmosphere and also influences estimates of melt production inferred from the history of surface volcanism. We consider several possible controls on the prevalence of intrusive magmatism at Tharsis and Syrtis Major, including melt production rates, lithospheric properties, regional stresses and strain rates, and magmatic volatile budgets. The Curie temperature is the minimum crustal temperature required for thermal demagnetization, implying that if the primary magnetic mineral is magnetite or hematite, the crust was warm during the intrusive magmatism reflected in Tharsis and Syrtis Major I/E ratios. When wall rocks are warm, thermally activated creep relaxes stresses from magma replenishment and regional tectonics, and eruptibility depends on buoyancy overpressure. We develop a new one‐dimensional model for the development of buoyancy in a viscous regime that accounts for cooling, crystallization, volatile exsolution, bubble coalescence and rise, fluid egress, and compaction of country rock. Under these conditions, we find that initial water and CO2 contents typically <1.5 wt % can explain the observed range of intrusive/extrusive ratios. Our results support the hypothesis that warm crust and a relatively sparse volatile budget encouraged the development of large intrusive complexes beneath Tharsis and Syrtis Major.

show abstract

The influence of lithospheric flexure on magma ascent at large volcanoes on Venus

Cited by 33 publications

References 67 publications

Signatures of Lithospheric Flexure and Elevated Heat Flow in Stereo Topography at Coronae on Venus

Signatures of Lithospheric Flexure and Elevated Heat Flow in Stereo Topography at Coronae on Venus

The history of tectonism on Venus: A stratigraphic analysis

The eruptibility of magmas at Tharsis and Syrtis Major on Mars

Contact Info

Product

Resources

About