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The AAPG/Datapages Combined Publications Database
Houston Geological Society Bulletin
Abstract
2010 Fall SEG/AAPG Distinguished Lecturer
Abstract: Rumblings from the Laboratory:
Past, Present, and Future
University of Oklahoma, Norman
The complexity of rocks in nature, and its
resultant imprint on rock properties,
makes empirical laboratory studies necessary
and relevant. Numerous efforts are currently
trying to use theoretical models to predict
petrophysical and seismic
rock properties from
microscale images of rocks. However,
modeling
can only honor the physics of the chosen
model; measurements are still needed to define
and calibrate this physics. Historically, laboratory
measurements have been used to develop an
understanding of the physical response of rock
and fluid systems under various conditions
(frequency, temperature, stress, sample size,
etc.). Early work was conducted to develop a
better understanding of the correlations
between compressional velocities, composition,
density, porosity, and pore fluid type; this
proved crucial to understanding sonic logs
and
seismic
bright spots. The ability to
measure shear and polarized shear velocities
significantly expanded the applicability of rock
physics to geophysical and engineering
problems. Combining P and S-wave data,
along with concepts of elasticity, provided the
basis for lithology and fluid discrimination.
Experimental confirmation of the Biot-
Gassmann theory provided rock physics with
one of the most important tools for the analysis
of prestack
seismic
data.
New directions in rock physics research will
extend the application by incorporating petrophysical
characterization into our measurement. Concepts of capillarity
and wettability are rarely incorporated into seismic
modeling
;
however, both control fluid saturation and distribution.
Promising future rock physics research include examination of
the effects of pore microstructure on elasticity, examination of
velocity behavior at temperatures and pressures equivalent to
those found in deep basins, and the effects of CO2 and time on
seismic
wave propagation through reservoir rocks. Simultaneous
measurements of multiple properties will provide stronger
modeling
constraints. Application of new measurement and
imaging technologies will allow us to extract more information
from smaller and smaller samples, including samples from drill
cuttings.
Our history is rich with examples of how laboratory measurements have lead to innovations in field-scale technologies. This talk will highlight past accomplishments in rock physics, and more importantly, will focus on future directions in rock physics and the promising and critical role of laboratory measurements in the development of new and innovative technologies.