Microbially Mediated Mineral Carbonation: Roles of Phototrophy and Heterotrophy

• Published in: Environmental science & technology Vol. 45; no. 20; pp. 9061 - 9068
• Main Authors: Power, Ian M., Wilson, Sasha, Small, Darcy P., Dipple, Gregory M., Wan, Wankei, Southam, Gordon
• Format: Journal Article
• Language: English
• Published: Washington, DC American Chemical Society 15.10.2011
• Subjects: Applied sciences; Biodegradation, Environmental; Biomass; Carbon Dioxide - metabolism; Carbon sequestration; Chemical precipitation; Climatology. Bioclimatology. Climate change; Earth, ocean, space; Emissions control; Energy and the Environment; Exact sciences and technology; External geophysics; Heterotrophic Processes - physiology; Meteorology; Minerals; Minerals - metabolism; Mines; Mining; Other industrial wastes. Sewage sludge; Phototrophic Processes - physiology; Pollution; Wastes; Water Microbiology; Australia; Western Australia; Oceania; Canada; Western Australia Australia; Phototrophy; Microbial activity; Chemical precipitation; Heterotrophy; CO2 sequestration; Sustainable development; Carbon sequestration; Tailings; Dynamical climatology; Mitigation; Climate change; Biogeochemistry; Biotransformation; Greenhouse gas; Solid waste; Carbonation; Leachate; Mining waste
• ISSN: 0013-936X; 1520-5851
• DOI: 10.1021/es201648g

Ultramafic mine tailings from the Diavik Diamond Mine, Canada and the Mount Keith Nickel Mine, Western Australia are valuable feedstocks for sequestering CO2 via mineral carbonation. In microcosm experiments, tailings were leached using various dilute acids to produce subsaline solutions at circumneutral pH that were inoculated with a phototrophic consortium that is able to induce carbonate precipitation. Geochemical modeling of the experimental solutions indicates that up to 2.5% and 16.7% of the annual emissions for Diavik and Mount Keith mines, respectively, could be sequestered as carbonate minerals and phototrophic biomass. CO2 sequestration rates are mainly limited by cation availability and the uptake of CO2. Abundant carbonate mineral precipitation occurred when heterotrophic oxidation of acetate acted as an alternative pathway for CO2 delivery. These experiments highlight the importance of heterotrophy in producing sufficient DIC concentrations while phototrophy causes alkalinization of waters and produces biomass (fatty acids = 7.6 wt.%), a potential feedstock for biofuel production. Tailings storage facilities could be redesigned to promote CO2 sequestration by directing leachate waters from tailings piles into specially designed ponds where carbonate precipitation would be mediated by both chemical and biological processes, thereby storing carbon in stable carbonate minerals and potentially valuable biomass.