Abstract
Subduction zones are likely a major source of compositional heterogeneities in the mantle, which may preserve a record of the subduction history and mantle convection processes. The fine-scale structure associated with mantle heterogeneities can be studied using the scattered seismic wavefield that arrives as coda to or as energy preceding many body wave arrivals. In this study we analyse precursors to PP by creating stacks recorded at globally distributed stations. We create stacks aligned on the PP arrival in 5° distance bins (with range 70–120°) from 600 earthquakes recorded at 193 stations stacking a total of 7320 seismic records. As the energy trailing the direct P arrival, the P coda, interferes with the PP precursors, we suppress the P coda by subtracting a best fitting exponential curve to this energy. The resultant stacks show that PP precursors related to scattering from heterogeneities in the mantle are present for all distances. Lateral variations are explored by producing two regional stacks across the Atlantic and Pacific hemispheres, but we find only negligible differences in the precursory signature between these two regions. The similarity of these two regions suggests that well mixed subducted material can survive at upper and mid-mantle depth. To describe the scattered wavefield in the mantle, we compare the global stacks to synthetic seismograms generated using a Monte Carlo phonon scattering technique. We propose a best-fitting layered heterogeneity model, BRT2017, characterised by a three layer mantle with a background heterogeneity strength (ϵ=0.8%) and a depth-interval of increased heterogeneity strength (ϵ=1%) between 1000 km and 1800 km. The scalelength of heterogeneity is found to be 8 km throughout the mantle. Since mantle heterogeneity of 8 km scale may be linked to subducted oceanic crust, the detection of increased heterogeneity at mid-mantle depths could be associated with stalled slabs due to increases in viscosity, supporting recent observations of mantle viscosity increases due to the iron spin transition at depths of ∼1000 km.
Highlights
Mantle convection is the process that drives the interaction of tectonic plates and recycles oceanic lithosphere introduced into the mantle at subduction zones
Tomographic studies have imaged fast velocity features associated with subducted slabs, some of which are continuous from the surface to the core–mantle boundary (CMB) (e.g. Van der Hilst et al, 1997)
The heterogeneity structure in the lithosphere and mantle is characterised through forward modelling of the scattered wavefield using a 1D Monte Carlo phonon method (Shearer and Earle, 2004) and the resulting synthetic envelopes are compared to the observed global stacks
Summary
Mantle convection is the process that drives the interaction of tectonic plates and recycles oceanic lithosphere introduced into the mantle at subduction zones. The crust deforms slowly over time in reaction to convection related stresses (Stixrude and Lithgow-Bertelloni, 2012) leading to long-lived heterogeneity that preserves the path taken by subduction These heterogeneities have scale lengths on the order of ∼10 km and are below the current resolution levels of global tomography models (>100 km). We consider models with constant heterogeneity in the mantle and increase model complexity by varying heterogeneity with depth to gain insight into the resultant effect of different scattering distributions on the PP precursory wavefield. The heterogeneity structure in the lithosphere and mantle is characterised through forward modelling of the scattered wavefield using a 1D Monte Carlo phonon method (Shearer and Earle, 2004) and the resulting synthetic envelopes are compared to the observed global stacks. We focus on the contribution from the mantle by considering radial variations in scattering scale length and Root Mean Square (RMS) velocity perturbations, and find the best fitting model overall has depth varying velocity perturbation
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