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Elastic wave radiation from borehole seismic sources in anisotropic mediaby Submitted to the Department of Earth, Atmospheric, and Planetary Sciences on December 14, 1993 in partial fulfillment of the requirements for the degree of Doctor of Philosophy ABSTRACT
This thesis is concerned with wave radiation and propagation from borehole
seismic sources in homogeneous and inhomogeneous anisotropic media, with focus
on the investigation of borehole influence on downhole source radiation.
First, numerically feasible dynamic and static Green's functions in transversely
isotropic media are obtained in dyadic form by evaluating in general a 2-D
inverse Laplacian operator involved in previous dynamic Green's function
expressions. This evaluation is of particular importance for the later BEM
implementation because of off-centered sources. The final dyadic form is similar
to that of the isotropic dyadic Green's function, therefore, it lends
itself to easy analytical and numerical manipulations. The dynamic Green's
function is expressed through three scalar quantities characterizing the propagation
of SH, P-SV, and P-SV-SH waves. The static Green's function
has the same dyadic form as the dynamic Green's function and the three
corresponding scalar functions are derived, From the dynamic Green's function,
displacements due to vertical, horizontal, and explosive sources are explicitly
given. The singular properties of the Green's functions are addressed
through their surface integrals within the limits of coinciding receiver and
source. The singular contribution is shown to be -1/2 when the static
stress Green's function is integrated over a half elliptical surface.
These results are directly applicable to the later BEM implementation.
Following the discussion of Green's functions, analytical radiation patterns
of three typical downhole seismic sources in transversely isotropic (TI) media
are obtained through asymptotic evaluation of displacement integrals. The
radiation patterns are expressed in terms of the slowness components of a
particular point on the slowness surface of the medium. This particular point,
known as the saddle point of the displacement integrals, is easily determined
by geometric arguments based on the slowness and wave surfaces of the TI medium.
Since the saddle point determines ray direction, the radiation patterns can
be readily incorporated into existing ray modeling codes to account for borehole
source effects. The analytical results show that borehole source radiation
patterns are independent of the source frequency if the product of frequency
if the product of frequency with borehole radius is much smaller than the
sound speed of the borehole fluid. This independence is true for most crosshole
experiments with source frequency up to 1 kHz. Numerical test results show
that the anisotropy effect on P- wave pattern is relatively moderate.
On the contrary, its effect on the S wave pattern is prominent even
for low degrees of P and S wave anisotropy. In the isotropic
limit, previous analytical results for isotropic medium are recovered. For
sources in cased borehole, casing and cement affect both wave amplitudes and
radiation patterns.
In chapter 4, a modeling technique based on the boundary element method is
established for modeling source radiation from open or cased boreholes in
layered TI media. The axis of symmetry of TI layers is assumed to be parallel
with the borehole axis. Under this assumption, the problem is significantly
simplified because the element discretization of the borehole remains one
dimensional. For open boreholes, three equivalent sources on each element
are assumed to represent the boundary effects on the inner fluid and the outer
solid. Three boundary conditions set up a system of equations for the equivalent
sources on all elements. Once the sources are known, displacements in the
solid and pressure in the fluid are obtained. For cased boreholes, the method
treats borehole fluid, and casing and cement as a cylindrically layered isotropic
medium. In this case, the boundary conditions to be satisfied at the borehole
wall are four (continuity of the normal and tangential displacements and stresses).
Thus, more computation is required to solve the system of equations. The implementation
of the method is illustrated through several examples.
Using the technique developed in Chapter 4, a Cross-well hydrophone data
set is analyzed in Chapter 5. Two other modelings, one with no boreholes and
one with a receiver borehole only, are used for comparison. The results show
that synthetic and real data agree with each other very well only when the
source borehole stems from the fact that the local geology contains high-contrast
sedimentary rocks. Since most of the source energy travels along the source
borehole as a tube wave, at high-contrast interfaces tube-to-shear wave conversion
is no longer a negligible secondary effect. In fact, as the data and the modeling
results suggest, shear waves due to tube wave conversion are even stronger
than the primary shear waves. The data and the modeling results also illustrate
that, when sandwiched between high velocity layers, a low velocity channel
traps tube wave-converted energy and guides it to the receiver borehole to
excite tube waves.
Finally, two special borehole sources are modeled analytically and numerically.
For the Downhole Orbital Vibrator, actual rotation of a radial force is incorporated
into a mathematical expression for the source. By using this source and the
Green's functions, the three displacement components in isotropic and
TI media are provided. Their numerical evaluation shows that the source may
be useful in detecting shear wave anisotropy. For a drill-bit source, the
BEM technique of Chapter 4 is extended to model its radiation pattern. Results
suggest that the borehole has little effect on drill-bit radiation.
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