On the mobilization of metals by CO2 leakage into shallow aquifers: exploring release mechanisms by modeling field and laboratory experiments

The dissolution of CO 2 in water leads to a pH decrease and a carbonate content increase in affected groundwater, which in turn can drive the mobilization of metals from sediments. The mechanisms of metal release postulated in various field and laboratory studies often differ. Drawing primarily on previously published results, we examine contrasting metal mobilization behaviors at two field tests and in one laboratory study, to investigate whether the same mechanisms could explain metal releases in these different experiments. Numerical modeling of the two field tests reveals that fast Ca‐driven cation exchange (from calcite dissolution) can explain the release of most major and trace metal cations at both sites, and their parallel concentration trends. The dissolution of other minerals reacting more slowly (superimposed on cation exchange) also contributes to metal release over longer time frames, but can be masked by fast ambient groundwater velocities. Therefore, the magnitude and extent of mobilization depends not only on metal‐mineral associations and sediment pH buffering characteristics, but also on groundwater flow rates, thus on the residence time of CO 2 ‐impacted groundwater relative to the rates of metal‐release reactions. Sequential leaching laboratory tests modeled using the same metal‐release concept as postulated from field experiments show that both field and laboratory data can be explained by the same processes. The reversibility of metal release upon CO 2 degassing by de‐pressurization is also explored using simple geochemical models, and shows that the sequestration of metals by resorption and re‐precipitation upon CO 2 exsolution is quite plausible and may warrant further attention. © 2015 Society of Chemical Industry and John Wiley & Sons, Ltd.

[1]  C. Tsang,et al.  Large-scale impact of CO2 storage in deep saline aquifers: A sensitivity study on pressure response in stratified systems , 2009 .

[2]  S. E. Drummond,et al.  Chemical evolution and mineral deposition in boiling hydrothermal systems , 1985 .

[3]  Giehyeon Lee,et al.  Geochemical implications of gas leakage associated with geologic CO2 storage--a qualitative review. , 2013, Environmental science & technology.

[4]  Liange Zheng,et al.  Evaluation of Potential Changes in Groundwater Quality in Response to CO2 Leakage from Deep Geologic Storage , 2010 .

[5]  Yue Hao,et al.  Geochemical detection of carbon dioxide in dilute aquifers , 2009, Geochemical transactions.

[6]  Yousif K. Kharaka,et al.  A Compilation of Rate Parameters of Water-Mineral Interaction Kinetics for Application to Geochemical Modeling , 2004 .

[7]  C. Appelo,et al.  Surface complexation of ferrous iron and carbonate on ferrihydrite and the mobilization of arsenic. , 2002, Environmental science & technology.

[8]  Liange Zheng,et al.  Effect of dissolved CO2 on a shallow groundwater system: a controlled release field experiment. , 2013, Environmental science & technology.

[9]  Andrew J Luhmann,et al.  Experimental observation of permeability changes in dolomite at CO2 sequestration conditions. , 2014, Environmental science & technology.

[10]  Jens T. Birkholzer,et al.  Geochemical modeling of changes in shallow groundwater chemistry observed during the MSU-ZERT CO2 injection experiment , 2012 .

[11]  Kevin G. Knauss,et al.  Reactive transport modeling of plug-flow reactor experiments: quartz and tuff dissolution at 240°C , 1998 .

[12]  Vincent Lagneau,et al.  Assessing the potential consequences of CO2 leakage to freshwater resources: A batch-reaction experiment towards an isotopic tracing tool , 2013 .

[13]  Jens Birkholzer,et al.  A shallow subsurface controlled release facility in Bozeman, Montana, USA, for testing near surface CO2 detection techniques and transport models , 2010 .

[14]  Jiemin Lu,et al.  Potential risks to freshwater resources as a result of leakage from CO2 geological storage: a batch-reaction experiment , 2010 .

[15]  E. Oelkers,et al.  SUPCRT92: a software package for calculating the standard molal thermodynamic properties of minerals, gases, aqueous species, and reactions from 1 to 5000 bar and 0 to 1000 ° C , 1992 .

[16]  Hari S. Viswanathan,et al.  Developing a robust geochemical and reactive transport model to evaluate possible sources of arsenic at the CO2 sequestration natural analog site in Chimayo, New Mexico , 2012 .

[17]  Karsten Pruess,et al.  TOUGHREACT Version 2.0: A simulator for subsurface reactive transport under non-isothermal multiphase flow conditions , 2011, Comput. Geosci..

[18]  Eric Proust,et al.  Inducing a CO2 leak into a shallow aquifer (CO2FieldLab EUROGIA+ project): Monitoring the CO2 plume in groundwaters , 2013 .

[19]  Kathryn L. Nagy,et al.  Chemical weathering rate laws and global geochemical cycles , 1994 .

[20]  E. Shock,et al.  Inorganic species in geologic fluids: correlations among standard molal thermodynamic properties of aqueous ions and hydroxide complexes. , 1997, Geochimica et cosmochimica acta.

[21]  F. Morel,et al.  Surface Complexation Modeling: Hydrous Ferric Oxide , 1990 .

[22]  R. Wilkin,et al.  Geochemical impacts to groundwater from geologic carbon sequestration: controls on pH and inorganic carbon concentrations from reaction path and kinetic modeling. , 2010, Environmental science & technology.

[23]  A. Navarre‐Sitchler,et al.  Metal release from limestones at high partial-pressures of CO2 , 2014 .

[24]  Rasmus Jakobsen,et al.  Hydro-geochemical impact of CO2 leakage from geological storage on shallow potable aquifers: A field scale pilot experiment , 2012 .

[25]  Chen Zhu,et al.  In situ feldspar dissolution rates in an aquifer , 2005 .

[26]  David R. Cole,et al.  Potential environmental issues of CO2 storage in deep saline aquifers: Geochemical results from the Frio-I Brine Pilot test, Texas, USA , 2009 .

[27]  Rajesh J. Pawar,et al.  The impact of CO2 on shallow groundwater chemistry: observations at a natural analog site and implications for carbon sequestration , 2010 .

[28]  D. L. Parkhurst,et al.  Critical Review of the Kinetics of Calcite Dissolution and Precipitation , 1979 .

[29]  M. Steven,et al.  Environmental consequences of potential leaks of CO2 in soil , 2011 .

[30]  R. Maxwell,et al.  Transformation of meta-stable calcium silicate hydrates to tobermorite: reaction kinetics and molecular structure from XRD and NMR spectroscopy , 2009, Geochemical transactions.

[31]  Carsten Vogt,et al.  Investigation of the geochemical impact of CO2 on shallow groundwater: design and implementation of a CO2 injection test in Northeast Germany , 2012, Environmental Earth Sciences.

[32]  Liange Zheng,et al.  A laboratory study of the initial effects of dissolved carbon dioxide (CO2) on metal release from shallow sediments , 2013 .

[33]  Katherine D. Romanak,et al.  Single-well push–pull test for assessing potential impacts of CO2 leakage on groundwater quality in a shallow Gulf Coast aquifer in Cranfield, Mississippi , 2013 .

[34]  D. Sapsford,et al.  Evolution of the chemistry of Fe bearing waters during CO2 degassing , 2012 .

[35]  E. C. Beutner Slaty cleavage and related strain in Martinsburg Slate, Delaware Water Gap, New Jersey , 1978 .

[36]  T. J. Wolery,et al.  Qualification of Thermodynamic Data for Geochemical Modeling of Mineral-Water Interactions in Dilute Systems , 2004 .

[37]  Jean-Michel Lemieux,et al.  Review: The potential impact of underground geological storage of carbon dioxide in deep saline aquifers on shallow groundwater resources , 2011 .

[38]  Rebecca C. Smyth,et al.  Assessing risk to fresh water resources from long term CO2 injection- laboratory and field studies , 2009 .

[39]  H. Helgeson,et al.  Summary and critique of the thermodynamic properties of rock forming minerals , 1978 .

[40]  Jens Birkholzer,et al.  On mobilization of lead and arsenic in groundwater in response to CO2 leakage from deep geological storage , 2009 .

[41]  Laurent Charlet,et al.  Surface catalysis of uranium(VI) reduction by iron(II) , 1999 .

[42]  Liange Zheng,et al.  Changes in the chemistry of shallow groundwater related to the 2008 injection of CO2 at the ZERT field site, Bozeman, Montana , 2010 .

[43]  Sookyun Wang,et al.  Dissolution of a mineral phase in potable aquifers due to CO2 releases from deep formations; effect of dissolution kinetics , 2004 .

[44]  R. Jackson,et al.  Potential impacts of leakage from deep CO2 geosequestration on overlying freshwater aquifers. , 2010, Environmental science & technology.

[45]  C. Appelo,et al.  Geochemistry, groundwater and pollution , 1993 .

[46]  A. Navarre‐Sitchler,et al.  Metal release from sandstones under experimentally and numerically simulated CO2 leakage conditions. , 2014, Environmental science & technology.

[47]  Jens T. Birkholzer,et al.  On modeling the potential impacts of CO2 sequestration on shallow groundwater: Transport of organics and co-injected H2S by supercritical CO2 to shallow aquifers , 2013 .

[48]  H. Allen,et al.  Chemical composition of bottled mineral water. , 1989, Archives of environmental health.