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GEOPHYSICAL RESEARCH LETTERS, VOL. 24, NO. 23, PAGES 3093–3096, 1997

Geoid and Topographic Swells Over Temperature-Dependent Thermal Plumes in Spherical-Axisymmetric Geometry

Scott D. King

Department of Earth and Atmospheric Sciences, Purdue University, West Lafayette, Indiana

Abstract

Geoid and topographic profiles over constant-viscosity thermal plumes in spherical-axisymmetric geometry at moderate Rayleigh numbers are compared with results from previous studies in other geometries. Plumes in spherical-axisymmetric models produce larger geoid anomalies than plumes in either Cartesian or cylindrical-axisymmetric geometries; however, the topographic anomalies over the plumes are smaller than the corresponding anomalies in a cylindrical-axisymmetric geometry but larger than those in a Cartesian geometry. For plumes in a temperature-dependent viscosity fluid, the geoid and topographic profiles are reduced by a factor of two when compared to a constant viscosity fluid with the same background viscosity profile. In this case, the radially-averaged temperature profile around the plume creates a low-viscosity ‘layer’ beneath the lithosphere.

Received 15 July 1997; accepted 6 October 1997.

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Citation: King, S. D. (1997), Geoid and Topographic Swells Over Temperature-Dependent Thermal Plumes in Spherical-Axisymmetric Geometry, Geophys. Res. Lett., 24(23), 3093–3096.

Copyright 1997 by the American Geophysical Union.