Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada
Potential environmental risks of constructing waste piles from sulphide-bearing salinesodic overburden include acid-mine drainage and salinization of surface soils. Acid-mine drainage may result from the production of sulphuric acid during the oxidation of sulphide minerals. Acid production during t...
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University of Saskatchewan
2005
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| Online Access: | http://hdl.handle.net/10388/etd-07112012-152130 |
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ftusaskatchewan:oai:harvest.usask.ca:10388/etd-07112012-152130 |
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ftusaskatchewan:oai:harvest.usask.ca:10388/etd-07112012-152130 2023-05-15T16:17:40+02:00 Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada Wall, Susan N. Hendry, Jim 2005 http://hdl.handle.net/10388/etd-07112012-152130 en_US eng University of Saskatchewan http://hdl.handle.net/10388/etd-07112012-152130 TC-SSU-07112012152130 text Thesis 2005 ftusaskatchewan 2022-05-14T22:10:23Z Potential environmental risks of constructing waste piles from sulphide-bearing salinesodic overburden include acid-mine drainage and salinization of surface soils. Acid-mine drainage may result from the production of sulphuric acid during the oxidation of sulphide minerals. Acid production during the oxidation of sulphide minerals may also increase the concentrations of S0₄ (from sulphuric acid), Ca (from dissolution of carbonates), and Na (from cation exchange with saline-sodic overburden) in surface soils. To identify and quantify these potential environmental risks, in situ S0₄ and Ca production rates were calculated using two different methods. Sulphide mineral oxidation rates were calculated using simple one-dimensional analytical modelling (assuming diffusive gas transport) of in situ pore-gas 0₂ concentrations. Ca loading from carbonate mineral dissolution (resulting in C0₂ production) was also calculated using the simple one-dimensional modelling of measured pore-gas C0₂ concentrations. Mass balance calculations using solid sample chemistry (total S, soluble ion and TIC concentrations) were also used to quantify the rate of S0₄ and Ca production rates. Geochemical and geotechnical parameters controlling acid production and salt loadings were measured by installing gas probes to a depth of 25 m (n = 34) for in situ pore-gas 0₂, C0₂, CH₄ and N₂ concentrations, and δ¹³Cc₀₂ values), diviner tubes to depths of 1.6 m (n = 3; for shallow moisture contents), a neutron access tube to 25 m (for deep moisture contents), and a thermistor string to 20m (for temperatures). Pore-gas 0₂, C0₂, CH₄ and N₂ concentrations were measured using a field-portable gas chromatograph. Depth profiles of solid sulphur (samples stored in anaerobic chambers) and carbon concentrations and forms were measured and used for acid-base accounting. Pore-gas chemistry showed that 0₂ concentrations decreased from atmospheric to less than 13% at 5 m depth. C0₂ concentrations increased from atmospheric (0.04%) to less than 4% at the same depth ... Thesis Fort McMurray University of Saskatchewan: eCommons@USASK Canada Fort McMurray |
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Open Polar |
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University of Saskatchewan: eCommons@USASK |
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ftusaskatchewan |
| language |
English |
| description |
Potential environmental risks of constructing waste piles from sulphide-bearing salinesodic overburden include acid-mine drainage and salinization of surface soils. Acid-mine drainage may result from the production of sulphuric acid during the oxidation of sulphide minerals. Acid production during the oxidation of sulphide minerals may also increase the concentrations of S0₄ (from sulphuric acid), Ca (from dissolution of carbonates), and Na (from cation exchange with saline-sodic overburden) in surface soils. To identify and quantify these potential environmental risks, in situ S0₄ and Ca production rates were calculated using two different methods. Sulphide mineral oxidation rates were calculated using simple one-dimensional analytical modelling (assuming diffusive gas transport) of in situ pore-gas 0₂ concentrations. Ca loading from carbonate mineral dissolution (resulting in C0₂ production) was also calculated using the simple one-dimensional modelling of measured pore-gas C0₂ concentrations. Mass balance calculations using solid sample chemistry (total S, soluble ion and TIC concentrations) were also used to quantify the rate of S0₄ and Ca production rates. Geochemical and geotechnical parameters controlling acid production and salt loadings were measured by installing gas probes to a depth of 25 m (n = 34) for in situ pore-gas 0₂, C0₂, CH₄ and N₂ concentrations, and δ¹³Cc₀₂ values), diviner tubes to depths of 1.6 m (n = 3; for shallow moisture contents), a neutron access tube to 25 m (for deep moisture contents), and a thermistor string to 20m (for temperatures). Pore-gas 0₂, C0₂, CH₄ and N₂ concentrations were measured using a field-portable gas chromatograph. Depth profiles of solid sulphur (samples stored in anaerobic chambers) and carbon concentrations and forms were measured and used for acid-base accounting. Pore-gas chemistry showed that 0₂ concentrations decreased from atmospheric to less than 13% at 5 m depth. C0₂ concentrations increased from atmospheric (0.04%) to less than 4% at the same depth ... |
| author2 |
Hendry, Jim |
| format |
Thesis |
| author |
Wall, Susan N. |
| spellingShingle |
Wall, Susan N. Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada |
| author_facet |
Wall, Susan N. |
| author_sort |
Wall, Susan N. |
| title |
Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada |
| title_short |
Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada |
| title_full |
Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada |
| title_fullStr |
Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada |
| title_full_unstemmed |
Characterizing the geochemical reactions in overburden waste pile : Synerude Mine Site, Fort McMurray, Alberta, Canada |
| title_sort |
characterizing the geochemical reactions in overburden waste pile : synerude mine site, fort mcmurray, alberta, canada |
| publisher |
University of Saskatchewan |
| publishDate |
2005 |
| url |
http://hdl.handle.net/10388/etd-07112012-152130 |
| geographic |
Canada Fort McMurray |
| geographic_facet |
Canada Fort McMurray |
| genre |
Fort McMurray |
| genre_facet |
Fort McMurray |
| op_relation |
http://hdl.handle.net/10388/etd-07112012-152130 TC-SSU-07112012152130 |
| _version_ |
1766003566521090048 |