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Mantle Convection and Surface Expressions


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verges of the relevant pressure–temperature space. Additional uncertainties arise from extrapolating the thermal or vibrational properties of minerals beyond the limitations of underlying assumptions, such as the quasi-harmonic approximation. For example, anharmonic contributions to elastic properties at high temperatures are mostly ignored as they remain difficult to assess in experiments and computations. Cobden et al. (2008) have explored how different combinations of finite‐strain equations and thermal corrections, including anelastic contributions, affect the outcomes of mineral‐physical models.

      Whether derived from experiments or computations, elastic properties are affected by uncertainties that need to be propagated into the uncertainties on finite‐strain parameters. Inverting elasticity data on a limited number of pressure–temperature combinations to find the optimal set of finite‐strain parameters will inevitably result in correlations between finite‐strain parameters. The uncertainties on derived finite‐strain parameters are only meaningful when the uncertainties on the primary data have been assessed correctly, a requirement that can be difficult to meet in particular for first‐principle computations. Uncertainties on modeled seismic properties of rocks arise from uncertainties on individual finite‐strain parameters and from the anisotropy of the rock‐forming minerals as captured by the bounds on the elastic moduli. When constructing mineral‐physical models, uncertainties have been addressed by varying the parameters that describe the elastic properties of minerals in a randomized way within their individual uncertainties (Cammarano et al., 2003; Cammarano et al., 2005a; Cobden et al., 2008). While capturing the combined variance of the models, randomized sampling of parameters cannot disclose how individual parameters or properties affect the model. Identifying key properties might help to define future experimental and computational strategies to better constrain the related parameters in mineral‐physical models.

      To illustrate how modeled seismic properties of mantle rocks are affected by different sources of uncertainties, I first concentrate on the properties of monomineralic and isotropic aggregates of major minerals in Earth’s upper mantle, transition zone, and lower mantle, i.e., olivine, wadsleyite and ringwoodite, and bridgmanite. For these minerals, complete elastic stiffness tensors have been determined together with unit cell volumes for relevant compositions and at relevant pressures. Such data sets can be directly inverted for the parameters of the cold parts of finite‐strain expressions for the components of the elastic stiffness tensor. For olivine compositions with Mg/(Fe+Mg) = 0.9, i.e., San Carlos olivine, high‐pressure elastic stiffness tensors at room temperature (Zha et al., 1998) can be combined with recent experiments at simultaneously high pressures and high temperatures (Mao et al., 2015; Zhang & Bass, 2016) to self‐consistently constrain most anisotropic finite‐strain parameters. For wadsleyite and ringwoodite, recent experimental results on single crystals (Buchen et al., 2018b; Schulze et al., 2018) are combined with tabulated parameters for the isotropic thermal contributions (Stixrude & Lithgow‐Bertelloni, 2011). Similarly, high‐pressure elastic stiffness tensors of bridgmanite at room temperature (Kurnosov et al., 2017) are complemented with results of DFT computations (Zhang et al., 2013) and high‐pressure high‐temperature experiments on polycrystals (Murakami et al., 2012) that constrain the isotropic thermal contributions.

      For each mineral, P‐ and S‐wave velocities are computed using the Voigt‐Reuss‐Hill averages for bulk and shear moduli of an isotropic aggregate. The explored pressures and temperatures are spanned by two adiabatic compression paths that start 500 K above and below a typical adiabatic compression path for each mineral. To examine the impact of uncertainties on a given finite‐strain parameter, P‐ and S‐wave velocities are then recalculated by first adding (+) and then subtracting (–) the respective uncertainty to a given parameter leaving all other parameters unchanged. The resulting difference in velocities Δv = v+v is then compared to the original velocity vVRH as:

equation

      The effect of anisotropy is illustrated in the same way by using the Voigt (V) and Reuss (R) bounds on the moduli and setting Δv = vVvR. The velocity variations d lnv are mapped over relevant pressures and temperatures for olivine, wadsleyite, ringwoodite, and bridgmanite. Note that, for each of these minerals, the results of experiments and computations need to be substantially inter‐ and extrapolated across the respective pressure–temperature space.

      Aggregate P‐ and S‐wave velocities of olivine, wadsleyite, and bridgmanite all show variations of more than 1% due to elastic anisotropy as reflected in the differences between the Voigt and Reuss bounds. The elastic anisotropy of ringwoodite single crystals is known to be fairly small (Mao et al., 2012; Sinogeikin et al., 1998; Weidner et al., 1984). As a result, aggregate P‐ and S‐wave velocities differ by less than 0.5% for ringwoodite. For minerals with significant elastic anisotropy, including the major mantle minerals olivine, wadsleyite, and bridgmanite, uncertainties on wave velocities that arise from averaging over grains with different orientations may contribute substantially to absolute uncertainties as the actual elastic response of an isotropic polycrystalline aggregate may fall somewhere in between the bounds on elastic moduli. Note that alternative bounding schemes might provide tighter bounds on elastic moduli than the Voigt and Reuss bounds (Watt et al., 1976).

      In comparison to the impact of elastic anisotropy on aggregate elastic moduli and wave velocities, the pressure derivatives images and images do not appear to strongly affect wave velocities when varied within reported uncertainties. This observation reflects the common approach of experimental and computational methods to address the response of elastic properties to compression and hence to best constrain pressure derivatives. To a certain extent, the comparatively small leverage of pressure derivatives on elastic wave velocities justifies inter‐ and extrapolations of the finite‐strain formalism to pressures and temperatures not covered by experiments or computations. Along adiabatic compression paths of typical mantle rocks, for example, changes in elastic properties that result from compression or volume reduction surpass changes that result from the corresponding adiabatic increase in temperature.

      With the exception of the Debye temperature, the parameters describing the