Viscous Attenuation Of Acoustic Waves In Suspensions
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Massachusetts Institute of Technology. Earth Resources Laboratory
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A model for attenuation of acoustic waves in suspensions is proposed which includes
an energy loss due to viscous fluid flow around spherical particles. The expression
for the complex wavenumber is developed by considering the partial pressures acting
on the solid and fluid phases of the suspension. This is shown to be equivalent to
the results of the Biot theory for porous media in the limiting case where the frame
moduli vanish. Unlike earlier applications of the limiting case Biot theory, however,
a value for the attenuation coefficient is developed from the Stokes flow drag force
on a sphere instead of attempting to apply a permeability value to a suspension. If
the fluid and solid particle velocities have harmonic time dependence with angular
frequency w, the attenuation in this model is proportional to w2 at low frequencies and
approaches a constant value at high frequencies. The predicted attenuation is very
sensitive to the radius and density of the spherical particles. Accurate modeling of
observed phase velocities from suspensions of spherical polystyrene particles in water
and oil and successful inversion for kaolinite properties using attenuation and velocity
data from kaolinite suspensions at 100 kHz show that this viscous dissipation model
is a good representation of the effects controlling the propagation of acoustic waves in
these suspensions. Attenuation predictions are also compared to amplitude ratio data
from an oil-polystyrene suspension. The viscous effects are shown to be significant for
only a limited range of solid concentration and frequency by the reduced accuracy of
the model for attenuation in a kaolinite suspension at 1 MHz.
Date issued
1988Publisher
Massachusetts Institute of Technology. Earth Resources Laboratory
Series/Report no.
Earth Resources Laboratory Industry Consortia Annual Report;1988-09