TY - GEN
T1 - Reducing Geologic Uncertainty Associated With Microseismicity Potential in Carbon Storage Projects
AU - Leetaru, Hannes E.
AU - Bauer, Robert
AU - McBride, John H.
AU - Freiburg, Jared
N1 - AAPG Datapages/Search and Discovery Article #90308
AAPG Eastern Section 46th Annual Meeting, September 24-27, 2017
PY - 2017
Y1 - 2017
N2 - Carbon Capture and Storage (CCS) is on a cusp of moving from small volume CO2 injection test sites to large-scale commercial projects. The increased rate of injection will raise both the reservoir pressure and the volumetric (lateral and vertical) extent of the plume. A combined regional and site-specific approach to geologic characterization will be necessary to understand the uncertainty and potential risks, including microseismicity, involved with any injection program. The Cambrian Mt. Simon Sandstone is one of the most important formations for CO2 storage in the Continental United States. The sediments of the lower Mt. Simon were deposited in a Precambrian failed rift basin that formed during the breakup of the supercontinent of Rodinia in what is now the Illinois Basin. This rifting event accommodated deposition of over 2,600 ft (792 m) thick Mt. Simon siliciclastic sediments. Recently acquired 2D and 3D seismic reflection data and new deep wells in this area have led to a better understanding of the geologic risks for CCS. These new data suggest that some accommodation of Mt Simon sediments was accompanied by contemporaneous faulting in the lowermost Mt. Simon and Precambrian rocks. The preservation and architecture of Mt. Simon reservoir rocks may, in some areas, be controlled by Precambrian topography that was formed by faulting and by erosion into the underlying rhyolite basement. One million tonnes of CO2 have been injected into the Mt. Simon Sandstone at the Illinois Basin – Decatur Project (IBDP). Continuous seismic monitoring before, during, and after injection, shows that microseismicity increased during injection and occurs not only in the Mt. Simon, but also in the underlying Argenta clastics and Precambrian igneous rocks. An interpretation of site 3D seismic data suggests that much of the microseismicity is proximal to interpreted faults that extend from the basement up into the lowermost Mt. Simon strata. The faults near clusters of microseismic activity are critically oriented with respect to the maximum stress direction. The results of the IBDP indicates the assessment of microseismic potential associated with commercial-scale CCS requires not only identification of a suitable reservoir and its petrophysical characteristics, but also the extent and orientation of existing faults and their relation to regional stress orientation.
AB - Carbon Capture and Storage (CCS) is on a cusp of moving from small volume CO2 injection test sites to large-scale commercial projects. The increased rate of injection will raise both the reservoir pressure and the volumetric (lateral and vertical) extent of the plume. A combined regional and site-specific approach to geologic characterization will be necessary to understand the uncertainty and potential risks, including microseismicity, involved with any injection program. The Cambrian Mt. Simon Sandstone is one of the most important formations for CO2 storage in the Continental United States. The sediments of the lower Mt. Simon were deposited in a Precambrian failed rift basin that formed during the breakup of the supercontinent of Rodinia in what is now the Illinois Basin. This rifting event accommodated deposition of over 2,600 ft (792 m) thick Mt. Simon siliciclastic sediments. Recently acquired 2D and 3D seismic reflection data and new deep wells in this area have led to a better understanding of the geologic risks for CCS. These new data suggest that some accommodation of Mt Simon sediments was accompanied by contemporaneous faulting in the lowermost Mt. Simon and Precambrian rocks. The preservation and architecture of Mt. Simon reservoir rocks may, in some areas, be controlled by Precambrian topography that was formed by faulting and by erosion into the underlying rhyolite basement. One million tonnes of CO2 have been injected into the Mt. Simon Sandstone at the Illinois Basin – Decatur Project (IBDP). Continuous seismic monitoring before, during, and after injection, shows that microseismicity increased during injection and occurs not only in the Mt. Simon, but also in the underlying Argenta clastics and Precambrian igneous rocks. An interpretation of site 3D seismic data suggests that much of the microseismicity is proximal to interpreted faults that extend from the basement up into the lowermost Mt. Simon strata. The faults near clusters of microseismic activity are critically oriented with respect to the maximum stress direction. The results of the IBDP indicates the assessment of microseismic potential associated with commercial-scale CCS requires not only identification of a suitable reservoir and its petrophysical characteristics, but also the extent and orientation of existing faults and their relation to regional stress orientation.
KW - ISGS
UR - http://www.searchanddiscovery.com/author.html
M3 - Conference contribution
VL - 36
T3 - American Association of Petroleum Geologists International Conference Abstracts
BT - Abstracts; AAPG/SEG international conference and exhibition; 100 years of science fueling 100 years of prosperity
CY - Morgantown, West Virginia
ER -