2006 Philadelphia Annual Meeting (22–25 October 2006)

Paper No. 10
Presentation Time: 1:30 PM-5:30 PM

DISSOLVED INORGANIC CARBON EVOLUTION IN ACID MINE DRAINAGE IMPACTED WATERS: INSIGHTS FROM LABORATORY REACTORS


FONYUY, Ernest Wirnkor, Geological Sciences and Engineering, University of Missouri- Rolla, 127 McNutt Hall, 1870 Miner Circle, Rolla, MO 65409 and ATEKWANA, Eliot, Boone Pickens School of Geology, Oklahoma State University, 105 Noble Research Center, Stillwater, OK 74078, few437@umr.edu

AMD impacted water samples were collected from a spring, select stream stations, and groundwater and allowed to evolve in contact with the atmosphere in the laboratory. The objective was to determine how dissolved inorganic carbon (DIC) and the carbon isotope ratio of DIC (δ13CDIC) evolve in acid mine impacted stream water in the absence of in-stream processes (e.g. aquatic photosynthesis). Over time, the spring, stream water, and one groundwater sample showed decreases in Fe2+, pH, alkalinity, and DIC, while the δ13CDIC increased and SO42- remained nearly constant. One of the groundwater samples showed an increase in pH despite decreases in Fe2+, alkalinity, and DIC, increase in the δ13CDIC and nearly constant SO42-. The decreases in Fe2+ in the samples were concomitant with a general increase in dissolved oxygen. This suggest that Fe2+ from AMD impact was oxidized to Fe3+ and subsequently hydrolyzed to Fe(OH)3(s). This reaction produces protons which explain the temporal decrease in pH with decrease in Fe2+. The DIC loss pattern for water samples with decreasing pH was characteristic and showed rapid decline at lower pH which we attribute to pH induced loss. In these samples, the δ13CDIC increased between 1 to 4 0/00. This is in contrast to the groundwater sample which showed a systematic increase in pH while DIC and alkalinity decreased, due to equilibration with atmospheric CO2. For this groundwater sample, the δ13C increased ~90/00. The decrease in Fe2+ and pH coupled with decrease in alkalinity, DIC and enrichment of δ13C in the water samples impacted by AMD suggest that AMD evolution enhances CO2 exsolution. The results of this experiment showed that AMD evolution in receiving streams and the nature of CO2 loss from AMD impact can be determined from Fe2+, pH, DIC, and δ13CDIC.