TY - JOUR
T1 - Risks attributable to water quality changes in shallow potable aquifers from geological carbon sequestration leakage into sediments of variable carbonate content
AU - Cahill, Aaron G.
AU - Jakobsen, Rasmus
AU - Mathiesen, Tina Bay
AU - Jensen, Christian Kjær
N1 - Funding Information:
This work was conducted as part of the CO2-GS project ( http://co2gs.geus.net/ ) funded by the Danish Strategic Research Council . Special thanks are given to Flemming Larsen for providing the sediments from the Geological survey archives and Sinh Nguyen for laboratory assistance.
PY - 2013/11
Y1 - 2013/11
N2 - The consequences of CO2 leakage from geological sequestration into shallow aquifers must be fully understood before such geo-engineering technology can be implemented. A series of CO2 exposure batch reactor experiments were conducted utilizing 8 sediments of varying composition obtained from across Denmark including; siliceous, carbonate and clay materials. Sediments were exposed to CO2 and hydro-geochemical effects were observed in order to improve general understanding of trace metal mobility, quantify carbonate influence, assess risks attributable to fresh water resources from a potential leak and aid monitoring measurement and verification (MMV) program design. Results demonstrate control of water chemistry by sediment mineralogy and most significantly carbonate content, for which a potential semi-logarithmic relationship with pH and alkalinity was observed. In addition, control of water chemistry by calcite equilibrium was inferred for sediments containing >2% total inorganic carbon (TIC), whereby pH minima and alkalinity maxima of approximately 6 and 20mequiv./l respectively were observed. Carbonate dominated (i.e. >2% TIC) and mixed (i.e. clay containing) sediments showed the most severe changes in water chemistry with large increases in all major and trace elements coupled to minimal reductions in pH due to high buffering capacity. Silicate dominated sediments exhibited small changes in dissolved major ion concentrations and the greatest reductions in pH, therefore displaying the greatest propensity for mobilization of high toxicity pH sensitive trace species.
AB - The consequences of CO2 leakage from geological sequestration into shallow aquifers must be fully understood before such geo-engineering technology can be implemented. A series of CO2 exposure batch reactor experiments were conducted utilizing 8 sediments of varying composition obtained from across Denmark including; siliceous, carbonate and clay materials. Sediments were exposed to CO2 and hydro-geochemical effects were observed in order to improve general understanding of trace metal mobility, quantify carbonate influence, assess risks attributable to fresh water resources from a potential leak and aid monitoring measurement and verification (MMV) program design. Results demonstrate control of water chemistry by sediment mineralogy and most significantly carbonate content, for which a potential semi-logarithmic relationship with pH and alkalinity was observed. In addition, control of water chemistry by calcite equilibrium was inferred for sediments containing >2% total inorganic carbon (TIC), whereby pH minima and alkalinity maxima of approximately 6 and 20mequiv./l respectively were observed. Carbonate dominated (i.e. >2% TIC) and mixed (i.e. clay containing) sediments showed the most severe changes in water chemistry with large increases in all major and trace elements coupled to minimal reductions in pH due to high buffering capacity. Silicate dominated sediments exhibited small changes in dissolved major ion concentrations and the greatest reductions in pH, therefore displaying the greatest propensity for mobilization of high toxicity pH sensitive trace species.
KW - Batch reactor
KW - Carbon capture and storage
KW - Carbon dioxide
KW - Groundwater chemistry
KW - Leakage
KW - Trace metals
UR - http://www.scopus.com/inward/record.url?scp=84884338903&partnerID=8YFLogxK
U2 - 10.1016/j.ijggc.2013.08.018
DO - 10.1016/j.ijggc.2013.08.018
M3 - Article
AN - SCOPUS:84884338903
SN - 1750-5836
VL - 19
SP - 117
EP - 125
JO - International Journal of Greenhouse Gas Control
JF - International Journal of Greenhouse Gas Control
ER -