Title of article
Craton stability and longevity: The roles of composition-dependent rheology and buoyancy
Author/Authors
Wang، نويسنده , , Hongliang and van Hunen، نويسنده , , Jeroen and Pearson، نويسنده , , D. Graham and Allen، نويسنده , , Mark B.، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2014
Pages
10
From page
224
To page
233
Abstract
Survival of thick cratonic roots in a vigorously convecting mantle system for billions of years has long been studied by the geodynamical community. High strength of the cratonic root is generally considered to be the most important factor, but the role of lithospheric mantle depletion and dehydration in this strengthening is still debated. Geodynamical models often argue for a significant strength or buoyancy contrast between cratonic and non-cratonic mantle lithosphere, induced by mantle depletion and dehydration. But recent laboratory experiments argue for only a modest effect of dehydration strengthening. Can we reconcile laboratory experiments and geodynamical models?
form and discuss new numerical models to investigate craton stability and longevity with different composition-dependent rheology and buoyancy. Our results show that highly viscous and possibly buoyant cratonic root is essential to stabilise a geometry in which thick cratonic lithosphere and thinner non-cratonic lithosphere coexist for billions of years. Using non-Newtonian rheology, a modest strengthening factor of Δ η = 3 can protect compositionally buoyant cratonic roots from erosion by mantle convection for over billions of years. A larger strengthening factor ( Δ η = 10 ) can maintain long term craton stability even with little or no intrinsic buoyancy. Such composition-dependent rheology is comparable to the laboratory experiments. This implies that a strict isopycnic state of cratonic lithosphere may not be necessary for the preservation of a cratonic root, provided a sufficient level of compositional strengthening is present.
Keywords
composition-dependent rheology , Buoyancy , dehydration strengthening , Non-Newtonian rheology , craton stability
Journal title
Earth and Planetary Science Letters
Serial Year
2014
Journal title
Earth and Planetary Science Letters
Record number
2332293
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