Abstract
Earth’s magnetic field is generated by turbulent motion in its fluid outer core. Although the bulk of the outer core is vigorously convecting and well mixed, some seismic, geomagnetic and geodynamic evidence suggests that a global stably stratified layer exists at the top of Earth’s core. Such a layer would strongly influence thermal, chemical and momentum exchange across the core–mantle boundary and thus have important implications for the dynamics and evolution of the core. Here we argue that the relevant scenario is not global stratification, but rather regional stratification arising solely from the lateral variations in heat flux at the core–mantle boundary. Using our extensive suite of numerical simulations of the dynamics of the fluid core with heterogeneous core–mantle boundary heat flux, we predict that thermal regional inversion layers extend hundreds of kilometres into the core under anomalously hot regions of the lowermost mantle. Although the majority of the outermost core remains actively convecting, sufficiently large and strong regional inversion layers produce a one-dimensional temperature profile that mimics a globally stratified layer below the core–mantle boundary—an apparent thermal stratification despite the average heat flux across the core–mantle boundary being strongly superadiabatic.
Highlights
Utilising an extensive suite of nonmagnetic rotating convection simulations, we are able to systematically access the strongly nonlinear, rotationally constrained, turbulent flow regime most relevant to the Earth’s core. Within this regime we find that the bulk of the core remains actively convecting due to a strong net superadiabatic heat flow across the core-mantle boundary (CMB) and no global thermally stratified layer can form
We investigate regional inversion layers in the core using a suite of numerical simulations of nonmagnetic rotating convection that includes two patterns and two amplitudes of CMB heat flux heterogeneity
In all of our simulations we find that convectively-stable regions of thermal inversion can be maintained over large lateral and radial extents, the bulk of the core remains strongly convecting and well mixed on short length scales
Summary
We investigate regional inversion layers in the core using a suite of numerical simulations of nonmagnetic rotating convection that includes two patterns (see supplementary figure 1) and two amplitudes of CMB heat flux heterogeneity (see methods and our previous work[31]). If the regional inversion layers are sufficiently large and strong, the horizontally-averaged temperature gradient near the top of the core can become positive (figures 2, 3), an apparent global stratification despite the average heat flux across the CMB being strongly superadiabatic. Implications for Earth Previous dynamical modelling[16,24,32,33,34,35] has focussed on interactions between heterogeneous boundary conditions and global stratified layers at the top of the core, motivated by stratification origins assuming uniform compositional enrichment[20,21,22] or net subadiabatic CMB heat flux[13,18]. In our model the Large Low Velocity Provinces are associated with low CMB heat flux and regional inversion layers; the latitudinal and longitudinal extents of the two LLVPs are quite different, which could result in differing influences on core thermal structure and geomagnetic variation. Physics of the Earth and Planetary Interiors 214, 104–114 (2013)
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