Browse > Article
http://dx.doi.org/10.7857/JSGE.2015.20.1.019

The Effects of CO2 Released from Deep Geological Formations on the Dissolution Process of Galena in Shallow Subsurface Environments  

Nam, Jieun (Department of Energy Resources Engineering, Pukyong National University)
Wang, Sookyun (Department of Energy Resources Engineering, Pukyong National University)
Publication Information
Journal of Soil and Groundwater Environment / v.20, no.1, 2015 , pp. 19-27 More about this Journal
Abstract
If $CO_2$ stored for geological sequestration escapes from deep formations and is introduced to shallow aquifers, it dissolves into groundwater, creates acidic environments, and enhance mineral dissolution from rocks and soils. Among these minerals, dissolution and spread of hazardous trace metals can cause environmental problems with detrimental impacts on groundwater quality. This study aims to investigate geochemical effects of $CO_2$ in groundwater on dissolution of galena, the main mineral controlling the mobility of lead. A series of batch experiments are performed with granulated galena in $CO_2$ solutions under various experimental conditions for $CO_2$ concentration and reaction temperature. Results show that dissolution of galena is significantly enhanced under acidic environments so that both of equilibrium concentrations and dissolution rates of lead increase. For thermodynamic analysis on galena dissolution, the apparent rate constants and the activation energy for galena dissolution are calculated by applying rate law to experimental results. The apparent rate constants are $6.71{\times}10^{-8}mol/l{\cdot}sec$ at $15^{\circ}C$, $1.77{\times}10^{-7}mol/l{\cdot}sec$ at $25^{\circ}C$, $3.97{\times}10^{-7}mol/l{\cdot}sec$ at $35^{\circ}C$ and the activation energy is 63.68 kJ/mol. The galena dissolution is suggested to be a chemically controlled surface reaction, and the rate determining step is the dissociation of Pb-S bond of surface complex.
Keywords
$CO_2$; Galena; Lead; Dissolution; Activation Energy;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Wang, S. and Jaffe P.R., 2004, Dissolution of a mineral phase in potable aquifers due to CO2 releases from deep formations; effect of dissolution kinetics, Energ. Convers. Manage., 45, 2833-2848.   DOI
2 Zhang, S., Li, J., Whang, Y., and Hu, G., 2007, Dissolution kinetics of galena in acid NaCl solutions at 25-75℃. App. Geochem., 19, 835-841.
3 Zheng, L., Apps, J.A., Zhang, Y., Xu, T., and Birkholzer, J.T., 2009, On mobilization of lead and arsenic in groundwater in response to CO2 leakage from deep geological storage, Chem. Geol., 268, 281-297.   DOI
4 De Giudici, G., Rossi, A., Fanfani, L., and Lattanzi, P., 2005, Mechanisms of galena dissolution in oxygen-saturated solutions: evaluation of pH effect on apparent activation energies and mineral-water interface, Geochim. Cosmochim. Acta, 69, 2321-2331.   DOI
5 Eisler, R., 2000, Handbook of Chemical Risk Assessment: Health hazards to humans, plant, and animals, CRC Press, Boca Raton, 4141 p.
6 Karri, S.K., Saper, R.B., and Kales, S.N., 2008, Lead encephalopathy due to traditional medicines, Curr. Drug Saf., 3, 54-59.   DOI
7 Korea Ministry of Environment, 2009, Regulations for Drinking Water Quality Standards and Examination, Drinking Water Policy Division.
8 Kosnett, M.J., 2005, Lead. In: J. Brent, K.L. Wallace, K.K. Burkhart, S.D. Phillips, J.W. Donovan (eds.), Critical Care Toxicology, Elsevier Mosby, Philadelphia, p. 821-836.
9 Lasaga, 1981, Rate laws of chemical reactions, In: Lasaga, A.C., Kirkpatrick, R.J. (eds.), Kinetics of Geochemical Processes. Rev. Mineral. 8, 1-68.
10 Lashof, D.A. and Ahuja, D.R., 1990, Relative contributions of greenhouse gas emissions to global warming, Nature, 344, 529-531.   DOI
11 Lowell, S., Shields, J., Thomas, M.A., and Thommes, M., 2004, Characterization of Porous Solids and Powders Surface Area, Porosity, and Density, Springer Science, New York, 339 p.
12 Staudinger, K.C. and Roth, V.S., 1998, Occupational lead poisoning, Am. Fam. Physician, 57, 719-26.
13 Acero, P., Cama, J., and Ayora, C., 2007, Rate law for galena dissolution in acidic environment. Chem. Geol., 245, 219-229.   DOI
14 Aydogan, S., Aras, A., Ucar, G., and Erdemoglu, M., 2007, Dissolution Kinetics of galena in acetic acid solutions with hydrogen peroxide. Hydrometallugy, 89, 189-195.   DOI   ScienceOn
15 Bachu, S., 2008, CO2 storage in geological media: Role, means, status and barriers to deployment, Prog. Energ. Combust., 34, 254-273.   DOI
16 Bateman, K., Turner, G., Pearce, J. M., Noy, D. J., Birchall, D., and Rochelle, C.A., 2005, Large-scale column experiment: study of CO2, porewater, rock reactions and model test case, Oil Gas Sci. Technol., 60, 161-175.   DOI
17 Brown, T.E., Eugene, H., LeMay, H., Bursten, B.E., Murphy, C., Woodward, P., and Stoltzfus, M.E., 2014, Chemistry: The Cen-tral Science, 13th edition, Prentice Hall, New Jersey, 1248 p.
18 IPCC (Intergovernmental Panel on Climate Change), 2005, Carbon dioxide capture and storage, Cambridge University Press, Cambridge, 431 p.