The role of layer-induced anisotropy in seismic exploration
Publication date
1992
Authors
Hake, J.H.
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Document Type
Dissertation
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Abstract
184In
this thesis we focus on anisotropy caused by fine layering. We analyse
the conditions that must be satisfied so that fine layering is equivalent to
anisotropy. In the long-wavelength (or quasi-static) approximation an interval of
thickness H, consisting of a sequence of layers, is effectively homogeneous and
anisotropic to seismic wave propagation. This approximation implies that H is
much smaller than the seismic wavelength A. Closer inspection of this
approximation shows that the degree of equivalence depends on several
parameters. The equivalence is exact for infinitely long wavelengths. It is also
exact (for all wavelengths) for those waves which are not back-scattered at the
interfaces between the layers. This is the case when reflection coefficients are
zero. We use a simple model where the interval of thickness H consists of a N
times repeated set of two layers. These two layers form one period, the whole
interval consists of N periods. The wave field that propagates through this
sequence oflayers, consists of the sum of the primary wave and all the multiples.
The effective medium for a given wave number depends on the interference of
primary and multiples. For infinitely thin layers this results in an effectively
homogeneous medium, with a pseudo-primary that is delayed compared to the
primary wave.