| A systematic investigation was carried out to study the interactions between bitumen (or hexadecane) and minerals (quartz, kaolinite and illite) in aqueous solutions containing multivalent metal cations Ca2+, Mg2+ and Fe2+/Fe3+, in the absence and presence of organic complexing agents (oxalic acid, EDTA and citric acid). A range of experimental techniques, including coagulation measurement, visualization of bitumen-mineral attachment, metal ion adsorption measurement, zeta potential measurement, Fourier-transform infrared spectroscopy and X-ray photoelectron spectroscopic analyses, were employed in the investigation. Free energy changes of adsorption of metal cations on the minerals and bitumen were evaluated using the James & Healy thermodynamic model. Total interaction energies between the minerals and bitumen were calculated using classical DLVO theory.;It was observed that while the tested minerals showed varying degrees of mutual-coagulation with bitumen (or hexadecane), the presence of the multivalent metal cations could prominently increase the mutual coagulation. It was also found that such enhancement of the mutual coagulation was only significant when the metal cations formed first-order hydroxyl complexes (such as CaOH +, MgOH+, etc.) or metal hydroxides (such as Fe(OH) 3, Mg(OH)2, etc.). Therefore, the increase of the bitumen-mineral mutual coagulation by the metal cations was strongly pH dependent.;Organic complexing agents (oxalic acid, citric acid and EDTA) used in this study, citric acid in particular, significantly reduced or virtually eliminated the mutual coagulation between bitumen (or hexadecane) and minerals caused by metal cations Ca2+, Mg2+, Fe 2+ and Fe3+. Due to its ability to substantially lower the mutual coagulation between bitumen and mineral particles, citric acid was found the most effective in improving bitumen-mineral liberation in solutions containing the multivalent metal cations at pH 8--10. In small scale flotation experiments to recover the residual bitumen from Syncrude Froth Treatment Tailings, the addition of up to 2x10-3 mol/L citric acid improved the separation efficiency by 24 percentage points. The sequential additions of 1.5x10-3 mol/L citric acid and 30 mg/L polyacrylamide further increased the flotation separation efficiency, which was attributed to the improved liberation of bitumen from the minerals by the citric acid, and the flocculation of the liberated minerals fines by the polyacrylamide. The latter was expected to reduce the mechanical entrainment of the liberated mineral fines. Pretreatment of the Froth Treatment Tailings in an ultrasonic bath was also effective for bitumen liberation and recovery from the Froth Treatment Tailings.;Through measurements of zeta potentials of the minerals and adsorption densities of the metal cations on mineral surfaces, coupled with speciation diagrams, it was shown that the multivalent metal cations functioned in the studied systems through three distinctly different mechanisms. These included electrical double layer compression by the metal cations; adsorption of the first-order metal hydroxyl species; and adsorption of the metal hydroxides on the mineral particles. Reversibility of adsorption and analyses by X-ray photoelectron spectroscopy (XPS) and attenuated total reflectance Fourier-transform infrared spectroscopy (ATR-FTIR) indicated that the adsorption of the first-order metal hydroxyl species on quartz and kaolinite was through electrostatic attraction, while that of metal hydroxides was possibly through chemisorption.;It was also shown that classical DLVO theory could be used to describe and predict bitumen-mineral interactions with and without the presence of citric acid. The energy barriers for the interaction between bitumen and the minerals were greatly raised in the presence of citric acid, as a contribution to the repulsive electrical double layers interaction between bitumen droplets and mineral particles. |
