Flexural models of trench/outer rise topography of coronae on Venus with axisymmetric spherical shell elastic plates

Details Flexural models of trench/outer rise topography of coronae on Venus with axisymmetric spherical shell elastic plates Flexural models of trench/outer rise topography of coronae on Venus with axisymmetric spherical shell elastic plates

Dec 1992

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1992lpico.789...72m&link_type=abstract

In Lunar and Planetary Inst., Papers Presented to the International Colloquium on Venus p 72-73 (SEE N93-14288 04-91)

Mathematics

Elastic Bending, Elastic Plates, Lithosphere, Mathematical Models, Planetary Crusts, Planetary Geology, Spherical Shells, Tectonics, Topography, Venus Surface, Axisymmetric Bodies, Bending Moments, Deformation, Flexing, Loads (Forces), Plate Theory, Thickness, Venus (Planet)

Scientific paper

Magellan altimetry has revealed that many coronae on Venus have trenches or moats around their peripheries and rises outboard of the trenches. This trench/outer rise topographic signature is generally associated with the tectonic annulus of the corona. Sandwell and Schubert have interpreted the trench/outer rise topography and the associated tectonic annulus around coronae to be the result of elastic bending of the Venus lithosphere (though the tectonic structures are consequences of inelastic deformation of the lithosphere). They used two-dimensional elastic plate flexure theory to fit topographic profiles across a number of large coronae and inferred elastic lithosphere thicknesses between about 15 and 40 km, similar to inferred values of elastic thickness for the Earth's lithosphere at subduction zones around the Pacific Ocean. Here, we report the results of using axisymmetric elastic flexure theory for the deformation of thin spherical shell plates to interpret the trench/outer rise topography of the large coronae modeled by Sandwell and Schubert and of coronae as small as 250 km in diameter. In the case of a corona only a few hundred kilometers in diameter, the model accounts for the small planform radius of the moat and the nonradial orientation of altimetric traces across the corona. By fitting the flexural topography of coronae we determine the elastic thickness and loading necessary to account for the observed flexure. We calculate the associated bending moment and determine whether the corona interior topographic load can provide the required moment. We also calculate surface stresses and compare the stress distribution with the location of annular tectonic features.

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