TY - JOUR
T1 - Evaluating the regional geological characteristics of the St. Peter Sandstone and Everton Formation for CO2 storage in Southern Illinois
T2 - A case study on site-specific injection feasibility in Washington County, Illinois
AU - Khosravi, Mansour
AU - Askari Khorasgani, Zohreh
AU - Okwen, Roland T.
AU - Taft, Kendall
N1 - Publisher Copyright:
© 2024 The Authors
PY - 2025/2
Y1 - 2025/2
N2 - This study provides a detailed investigation of CO2 storage potential in the St. Peter Sandstone and Everton Formation in Southern Illinois, employing a comprehensive, multidisciplinary approach that integrates geological and petrophysical analysis, seismic evaluations, and reservoir modeling. The objective of this study is to thoroughly characterize the geological and petrophysical attributes of these formations, emphasizing the lithology, thickness, and spatial distribution of porosity and permeability. A regional geocellular model was developed to identify specific areas within the St. Peter Sandstone and Everton Formation with significant CO2 storage potential. The parameters used to identify these areas include average thickness, porosity, permeability, and brine salinity. The evaluation of the petrophysical logs and core intervals indicate that the St. Peter Sandstone is predominantly characterized by its fine to medium, well-sorted pure quartz sandstone composition, which is notably devoid of clay minerals. Furthermore, the Everton Formation exists locally in southwestern and southern Illinois and has two distinct intervals: the upper dolomite and the lower fine to medium grained, well-sorted quartz sandstone intervals. The Everton sandstone interval in southwest Illinois has reservoir properties similar to the St. Peter Sandstone. Regional variation in porosity and permeability is evident, with high porosity values in the west-central region of Illinois diminishing gradually towards the southern parts of the state. A portion of the regional geocellular model was used as input to dynamic reservoir simulation of CO2 injection via the Lively Grove 1 well in Washington County, Illinois. A 30-year injection phase and a 50-year post-injection phase were simulated. Dynamic reservoir simulations were performed to assess the long-term viability of securely storing CO2 within the St. Peter Sandstone and Everton Formation. Preliminary simulation results indicate that over two million metric tonnes of CO2 can be securely injected annually into the St. Peter Sandstone and Everton Formation via a single well, thereby underscoring the practical implications of the study's findings for effective CO2 management. Significantly, the study identifies the west-central part of Illinois as a highly suitable location for CO2 storage within these formations. This insight is instrumental for developing targeted CO2 storage strategies in the Illinois Basin, contributing to broader carbon mitigation efforts worldwide. The research emphasizes the role of geological storage in lowering atmospheric CO2 concentrations, marking a critical step forward in combating climate change. Moreover, it highlights the indispensable role of the St. Peter Sandstone and Everton Formation in advancing carbon storage techniques.
AB - This study provides a detailed investigation of CO2 storage potential in the St. Peter Sandstone and Everton Formation in Southern Illinois, employing a comprehensive, multidisciplinary approach that integrates geological and petrophysical analysis, seismic evaluations, and reservoir modeling. The objective of this study is to thoroughly characterize the geological and petrophysical attributes of these formations, emphasizing the lithology, thickness, and spatial distribution of porosity and permeability. A regional geocellular model was developed to identify specific areas within the St. Peter Sandstone and Everton Formation with significant CO2 storage potential. The parameters used to identify these areas include average thickness, porosity, permeability, and brine salinity. The evaluation of the petrophysical logs and core intervals indicate that the St. Peter Sandstone is predominantly characterized by its fine to medium, well-sorted pure quartz sandstone composition, which is notably devoid of clay minerals. Furthermore, the Everton Formation exists locally in southwestern and southern Illinois and has two distinct intervals: the upper dolomite and the lower fine to medium grained, well-sorted quartz sandstone intervals. The Everton sandstone interval in southwest Illinois has reservoir properties similar to the St. Peter Sandstone. Regional variation in porosity and permeability is evident, with high porosity values in the west-central region of Illinois diminishing gradually towards the southern parts of the state. A portion of the regional geocellular model was used as input to dynamic reservoir simulation of CO2 injection via the Lively Grove 1 well in Washington County, Illinois. A 30-year injection phase and a 50-year post-injection phase were simulated. Dynamic reservoir simulations were performed to assess the long-term viability of securely storing CO2 within the St. Peter Sandstone and Everton Formation. Preliminary simulation results indicate that over two million metric tonnes of CO2 can be securely injected annually into the St. Peter Sandstone and Everton Formation via a single well, thereby underscoring the practical implications of the study's findings for effective CO2 management. Significantly, the study identifies the west-central part of Illinois as a highly suitable location for CO2 storage within these formations. This insight is instrumental for developing targeted CO2 storage strategies in the Illinois Basin, contributing to broader carbon mitigation efforts worldwide. The research emphasizes the role of geological storage in lowering atmospheric CO2 concentrations, marking a critical step forward in combating climate change. Moreover, it highlights the indispensable role of the St. Peter Sandstone and Everton Formation in advancing carbon storage techniques.
KW - CO injection feasibility
KW - CO storage
KW - Dynamic reservoir simulation
KW - Everton Formation
KW - Geocellular model
KW - Geological study
KW - Petrophysical evaluation
KW - Reservoir modeling
KW - Seismic evaluation
KW - St. Peter Sandstone
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U2 - 10.1016/j.ijggc.2024.104292
DO - 10.1016/j.ijggc.2024.104292
M3 - Article
AN - SCOPUS:85211454985
SN - 1750-5836
VL - 141
JO - International Journal of Greenhouse Gas Control
JF - International Journal of Greenhouse Gas Control
M1 - 104292
ER -