Talk abstract:
The viscosity of the mantle affects every aspect of the thermal and compositional evolution of
Earth's interior. Radial variations in viscosity affect the sinking of slabs, the morphology of
plumes, and the rate of convective heat transport and thermal evolution. Below the mantle
transition zone, we detect changes in the long-wavelength pattern of lateral heterogeneity in
global tomographic models, a peak in the the depth-distribution of seismic scatterers, and
changes in the dynamics plumes and slabs, which may be associated with a change in viscosity.
We analyze the long-wavelength structures, radial correlation functions, and spectra of four
recent global tomographic models and a suite of geodynamic models. We find that the depth-
variations of the spectral slope in tomographic models are most consistent with a geodynamic
model that contains both a dynamically significant phase transition and a reduced-viscosity
region at the top of the lower mantle. We present new inferences of the mantle radial viscosity
profile that are consistent with the presence of such a feature.