The effect of depth‐dependent viscosity on convective mixing in the mantle and the possible survival of primitive mantle

1 June 1986

journal article
Published by American Geophysical Union (AGU) in Geophysical Research Letters

Vol. 13 (6) , 541-544
https://doi.org/10.1029/gl013i006p00541

Abstract

The effect depth‐dependent viscosity has on convective mixing and sampling (or degassing) of primitive mantle beneath ridges is explored in two‐dimensional models. Higher relative viscosities in the deep mantle decrease convection velocities and strain rates and prolong the residence time of material in the deep mantle. If the average viscosity of the lower mantle is at least 100 times the viscosity of the upper mantle, then some mantle material could have survived from very early in the earth's history. If, in addition, the depth of degassing under ridges has been less than 75 km, on average over earth history, then helium isotopic systematics are qualitatively consistent with whole mantle convection.

Keywords

This publication has 18 references indexed in Scilit:

Excess 3He in oceanic basalts: Evidence for terrestrial primordial helium
Published by Elsevier ,2002
Helium isotopic variations in volcanic rocks from Loihi Seamount and the Island of Hawaii
Published by Elsevier ,2002
Numerical study of high Rayleigh number convection in a medium with depth-dependent viscosity
Geophysical Journal International, 1986
Slab penetration into the lower mantle beneath the Mariana and other island arcs of the northwest Pacific
Journal of Geophysical Research, 1986
Simple parametric models of crustal growth
Journal of Geodynamics, 1985
Lower mantle heterogeneity, dynamic topography and the geoid
Nature, 1985
Heat and helium in the Earth
Nature, 1983
Constraints on evolution of Earth's mantle from rare gas systematics
Nature, 1983
Helium isotopic variations in the mantle beneath the central North Atlantic Ocean
Earth and Planetary Science Letters, 1982
The creep strength of the Earth's mantle
Reviews of Geophysics, 1970