Geologic formations and mine locations for potential CO2 mineralization
January 21, 2022
This geodatabase contains geologic unit boundaries and asbestos site locations shown in "Carbon dioxide mineralization feasibility in the United States" (Blondes and others, 2019). Data was compiled from source material at a scale range of 1:100,000 to 1:5,000,000 and is not intended for any greater detail.
Citation Information
Publication Year | 2022 |
---|---|
Title | Geologic formations and mine locations for potential CO2 mineralization |
DOI | 10.5066/P9D92L53 |
Authors | Madalyn S Blondes, Matthew Merrill, Steven T Anderson, Christina A DeVera, Lauren A Agyepong, Steven M Cahan |
Product Type | Data Release |
Record Source | USGS Asset Identifier Service (AIS) |
USGS Organization | Geology, Energy & Minerals Science Center |
Rights | This work is marked with CC0 1.0 Universal |
Related
Carbon dioxide mineralization feasibility in the United States
Geologic carbon dioxide (CO2) storage is one of many methods for stabilizing the increasing concentration of CO2 in the Earth’s atmosphere. The injection of CO2 in deep subsurface sedimentary reservoirs is the most commonly discussed method; however, the potential for CO2 leakage can create long-term stability concerns. This report discusses the feasibility of an alternative form of geologic CO2 s
Authors
Madalyn S. Blondes, Matthew D. Merrill, Steven T. Anderson, Christina A. DeVera
Madalyn S. Blondes, Ph.D.
Research Geologist
Research Geologist
Email
Phone
Matthew D. Merrill
Research Geologist
Research Geologist
Email
Phone
Christina A. DeVera
Physical Scientist
Physical Scientist
Email
Phone
Related
Carbon dioxide mineralization feasibility in the United States
Geologic carbon dioxide (CO2) storage is one of many methods for stabilizing the increasing concentration of CO2 in the Earth’s atmosphere. The injection of CO2 in deep subsurface sedimentary reservoirs is the most commonly discussed method; however, the potential for CO2 leakage can create long-term stability concerns. This report discusses the feasibility of an alternative form of geologic CO2 s
Authors
Madalyn S. Blondes, Matthew D. Merrill, Steven T. Anderson, Christina A. DeVera
Madalyn S. Blondes, Ph.D.
Research Geologist
Research Geologist
Email
Phone
Matthew D. Merrill
Research Geologist
Research Geologist
Email
Phone
Christina A. DeVera
Physical Scientist
Physical Scientist
Email
Phone