Multimode rayleigh wave inversion for heterogeneity and azimuthal anisotropy of the Australian upper mantle
Publication date
2002
Authors
Simons, J.-P.
Hilst, R.D. van der
Montagner, F.J.,
Zielhuis, A.
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Article
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Abstract
We present an azimuthally anisotropic 3-D shear-wave speed model of the Australian upper
mantle obtained from the dispersion of fundamental and higher modes of Rayleigh waves.We
compare two tomographic techniques to map path-average earth models into a 3-D model for
heterogeneity and azimuthal anisotropy. Method I uses a rectangular surface cell parametrization
and depth basis functions that represent independently constrained estimates of radial
earth structure. It performs an iterative inversion with norm damping and gradient regularization.
Method II uses a direct inversion of individual depth layers constrained by Bayesian
assumptions about the model covariance. We recall that Bayesian inversions and discrete regularization
approaches are theoretically equivalent, and with a synthetic example we show that
they can give similar results. The model we present here uses the discrete regularized inversion
of independent path constraints of Method I, on an equal-area grid. With the exception of
westernmost Australia, we can retrieve structure on length scales of about 250 km laterally
and 50 km in the radial direction, to within 0.8 per cent for the velocity, 20 per cent for the
anisotropic magnitude and 20◦ for its direction. On length scales of 1000 km and longer, down
to about 200 km, there is a good correlation between velocity heterogeneity and geologic age.
At shorter length scales and at depths below 200 km, however, this relationship breaks down.
The observed magnitude and direction of maximum anisotropy do not, in general, appear
to be correlated to surface geology. The pattern of anisotropy appears to be rather complex
in the upper 150 km, whereas a smoother pattern of fast axes is obtained at larger depth. If
some of the deeper directions of anisotropy are aligned with the approximately N–S direction
of absolute plate motion, this correspondence is not everywhere obvious, despite the fast
(7 cm yr−1) northward motion of the Australian plate. More research is needed to interpret our
observations in terms of continental deformation. Predictions of SKS splitting times and directions,
an integrated measure of anisotropy, are poorly matched by observations of shear-wave
birefringence.
Keywords
Australia, azimuthal anisotropy, heterogeneity, inversion, surface-waves, tomography