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Natural clinoptilolite for the removal of cobalt and copper from aqueous solutionsNyembe, Dumsile W. 02 March 2011 (has links)
M.Sc. / The metallurgical industrial losses of base metals with waste solutions are an environmental threat to water sources, hence these metal ions must be removed prior to discharge into receiving bodies. In this study, Southern African clinoptilolite’s capability as an ion-exchanger with respect to Cu2+ and Co2+ was investigated in order to consider its application in metal cation removal from aqueous solutions. The clinoptilolite was characterised with X-ray powder diffraction (XRD), X-ray fluorescence (XRF), FTIR, thermogravimetric analyser (TGA) and SEM-EDS. The clinoptilolite was found to be a thermally stable alumino-silicate with calcite, dolomite and quartz as the main minerals. Investigations of Co2+ and Cu2+ uptake were first performed on non-mixed solutions of these cations. It was found that Cu2+ was removed faster than Co2+ with removal efficiencies of 79% and 63% respectively. The column method was used in the cation-exchange processes with synthetic solutions of 0.0020 M, 0.0698 M and 0.2000 M of Co2+ and Cu2+ concentrations which were measured using atomic absorption spectroscopy (AAS). The effects of Co2+ and Cu2+ ions on one another’s removal efficiency were investigated on Co/Cu mixed synthetic solutions by varying their concentration ratios in solution. The Cu2+ was generally found to be removed at lower rates than the Co2+. Investigations on added impurities in the form of Si4+ and Fe2+ in the mixed Co/Cu synthetic solutions were carried out to determine their effect on the removal efficiencies of the targeted metals. It was found that both Si4+ and Fe2+ greatly reduced the removal efficiency of Cu2+, especially with increased amounts of Si4+ in the Co/Cu solution.
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Micro-organisms for the removal of copper and cobalt from aqueous solutionsDlamini, Nonjabulo Prudence 31 March 2010 (has links)
M.Sc. / Inorganic pollutants like heavy metals are some of the major water pollutants worldwide. They are toxic and in some cases carcinogenic even at low concentrations. Their removal from industrial aqueous solutions, wastewater and hydrometallurgical process solutions prior to their release to the environment is necessary for a healthy biosphere which includes human beings, aquatic life and plants. There are several technologies used to remove metals such as Cu, Co, Zn, Hg from water. These include among others, ion exchange, membrane filtration, activated carbon, electrochemical treatment, chemical precipitation, reverse osmosis, coagulation and flocculation. Although they have been used in the removal of metal pollutants from water, these technologies produce high quantities of sludge. They are also expensive to operate and need well trained personnel to operate large chemical plants. Since current metal removal techniques have limitations, a need exists for the development of environmentally friendly and cost effective techniques for the removal of metal ions from aqueous media. The focus of this research project is on the use of micro-organisms as biosorbents for copper and cobalt pollutants in aqueous solutions. The experimental work was carried out on a laboratory scale and a summary of our findings is presented as follows: Synthetic sulphate solutions of copper and cobalt were prepared using CuSO4. 7H2O and CoSO4. 5H2O powders. Concentrations of 0.002 M, 0.07 M and 0.2 M copper and cobalt ions in solution were used as test synthetic solutions for our experiments. Mixed strains of bioleaching bacteria were sourced from Mintek (Randburg, South Africa) to test the viability of this research project. This consortium contained Acidithiobacillus caldus, Leptospirillum spp, Ferroplasma spp and Sulphobacillus spp. These bacteria were able to remove up to 55% copper and 25% cobalt from low concentrated copper and cobalt sulphate solutions with 69% and 58% removal demonstrated in the case of mine effluents emanating from metallurgical operations. Different strains of micro-organisms (bacteria) were isolated from mine dumps and mine operation effluents and soil from the Palabora Mining Company in Limpopo, a northern province in South Africa and Nigel Town in the Gauteng Province. The isolated bacterial strains were then identified using PCR analysis and strains from the Bacillus genre were found to be predominant. Shewanella spp was also present. Pseudomonas spp was isolated using Pseudomonas agar base. These bacteria were then cultured at different species-specific culture conditions and their capabilities to remove copper and cobalt ions first from synthetic solutions and subsequently from mine effluents emanating from metallurgical operations were tested. In the first stage of biosorption experiments, factors that affect biosorption mechanisms which include, solution concentration, biomass concentration, pH, contact time and the presence of other metal co-ions were investigated. A decrease in the amount of metal sorbed as solution concentrations increased was observed with all the bacterial strains. An increase in metal sorption was also observed when biomass concentration was increased. The pH was found to be a species dependant parameter.
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Comparative investigation of copper knit-metal cloth and Raschig rings as absorption tower packingsSwitzer, William Owen January 1938 (has links)
Gas absorption may be defined as the transfer from a gas to a liquid of one or more components of a gaseous mixture by means of solution in a liquid. This is accomplished by bringing the two phases together, with a large amount of interfacial surface, in an economical manner for commercial use.
Much is lacking in knowledge of the theory of gas absorption. This lack of knowledge and the wide variety of purposes and specifications have caused many types of absorption equipment to be designed, built and used. The objective in all causes has been to increase the surface of contact between the gas and the liquid at low installation cost and with low operating costs.
The most common type of absorption equipment is the packed tower. It consists, essentially, of a vertical shell filled with an inert packing material. Absorption is accomplished by countercurrent operation, the solvent being allowed to trickle down over the packing material while the gas passes up through the wetted packing.
The tower packing is the fundamental consideration in improving the efficiency of the equipment. A packing material should have a low resistance to gas flow so as to give low maintenance costs, a high absorption capacity and low costs of installation. In any case, the packing that most completely fills the requirements should be used.
It is the purpose of this investigation to make a study of the characteristics of operation of copper knit-metal cloth, in comparison to Raschig rings, when used absorption tower packings. / Master of Science
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The effect of impurities, smootheners and other factors on the recovery of copper from solutionsNtengwa, Felix William 12 1900 (has links)
Thesis (M.Tech.) / The electrochemical refining of copper was investigated at different temperatures,
distances between electrodes, different levels of overvoltage, current density, metal
impurities, smootheners, electrode-active area and concentration of electrolyte using the
parallel-plate model. The purpose of the investigation was to evaluate the effect of
smootheners, impurities and other factors on the recovery of copper from solutions.
The results showed that the metal impurities, with more negative oxidation potentials,
did not affect the electro-deposition of copper whilst metals with oxidation potentials
close and equal to that of copper reduced the current efficiency. The current density
increased with the increase in temperature, overvoltage and concentration of electrolyte.
The increase in overvoltage and current density above limiting values produced
increased rates of deposition resulting in efficiencies greater than 100% to be attained.
The increase in the limiting current density at concentration below 10.8g/L produced
low values of current efficiency ranging from 100 to 30%. The 2 and 3cm distance
between electrodes produced stable efficiencies of between 92-100% and 96-100%
respectively. The temperature was found to have indirect effect on the current
efficiency but direct effect on the dissociation of electrolyte in solution, current density
and overvoltage. An increase of 20cm2 of electrode active area reduced the current
efficiency by about 40%. The increase in concentration of electrolyte produced an
increase in the current density and efficiency ranging from 75-100%. The use of
smootheners; thiourea and EDTA (Ethylenediaminetetraacetic acid) reduced the current
density and current efficiency (100>CE>30%). However increased concentration of Kglue,
B-glue and G-Arabic in conjunction with EDTA or thiourea and NaCl improved
the current efficiency even at increased levels of overvoltage to levels of 96-100%,
100% and 90-100% respectively. Therefore, the presence of impurities, the use of high
current densities, inadequate distance between electrodes, and too low concentration of
electrolyte and the absence of glue disadvantaged the recovery process while the
presence of K-glue and B-glue reduced the inhibition effects of thiourea and EDTA and
thus improved the recovery of copper from solutions.
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The effect of impurities, smootheners and other factors on the recovery of copper from solutionsNtengwa, Felix William 12 1900 (has links)
Thesis (M.Tech.) / The electrochemical refining of copper was investigated at different temperatures,
distances between electrodes, different levels of overvoltage, current density, metal
impurities, smootheners, electrode-active area and concentration of electrolyte using the
parallel-plate model. The purpose of the investigation was to evaluate the effect of
smootheners, impurities and other factors on the recovery of copper from solutions.
The results showed that the metal impurities, with more negative oxidation potentials,
did not affect the electro-deposition of copper whilst metals with oxidation potentials
close and equal to that of copper reduced the current efficiency. The current density
increased with the increase in temperature, overvoltage and concentration of electrolyte.
The increase in overvoltage and current density above limiting values produced
increased rates of deposition resulting in efficiencies greater than 100% to be attained.
The increase in the limiting current density at concentration below 10.8g/L produced
low values of current efficiency ranging from 100 to 30%. The 2 and 3cm distance
between electrodes produced stable efficiencies of between 92-100% and 96-100%
respectively. The temperature was found to have indirect effect on the current
efficiency but direct effect on the dissociation of electrolyte in solution, current density
and overvoltage. An increase of 20cm2 of electrode active area reduced the current
efficiency by about 40%. The increase in concentration of electrolyte produced an
increase in the current density and efficiency ranging from 75-100%. The use of
smootheners; thiourea and EDTA (Ethylenediaminetetraacetic acid) reduced the current
density and current efficiency (100>CE>30%). However increased concentration of Kglue,
B-glue and G-Arabic in conjunction with EDTA or thiourea and NaCl improved
the current efficiency even at increased levels of overvoltage to levels of 96-100%,
100% and 90-100% respectively. Therefore, the presence of impurities, the use of high
current densities, inadequate distance between electrodes, and too low concentration of
electrolyte and the absence of glue disadvantaged the recovery process while the
presence of K-glue and B-glue reduced the inhibition effects of thiourea and EDTA and
thus improved the recovery of copper from solutions.
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Copper adsorption/desorption characteristics on copper amended soilsReed, Stewart T. 06 June 2008 (has links)
Laboratory tests were conducted to determine Cu availability of three Virginia soils amended with Cu as either Cu-rich pig manure or CuSO₄ with the same Cu content as that in manure. The study also assessed the capability of Mehlich-3 to estimate deficient and toxic Cu levels in soil. Application of Cu as manure or CuSO₄ did not affect grain yield or grain Cu concentration in corn grown at each site. Young corn plant height was reduced by CuSO₄ application on the Bertie sandy loam, an indication of greater toxicity from inorganic than organic Cu.
Very little exchangeable or solution Cu was present in any of the three soils. The vast majority of Cu was distributed between the organic and soil oxide fractions. The ratio of soil oxide to organic matter determines the relative distribution of Cu among these fractions. Most organically bound Cu was held by specific adsorption mechanisms and Mehlich-3 strongly extracts this fraction. Mehlich-3 extraction patterns were indicative of Cu binding strength in the different soils. Since Mehlich-3 strongly extracts specifically bound Cu and only poorly removes oxide Cu, this test may underestimate Cu availability on sandy soils with low organic matter content. However, Mehlich-3 provides an acceptable test for soil Cu.
Soil sorption characteristics were studied for Cu, Pb, and Zn added, both alone and simultaneously. Copper sorption energy was higher than both Pb or Zn, however, sorption capacity followed the order Pb > Zn > Cu. High Pb and Zn sorption was in part due to precipitation reactions especially at high initial solution concentrations. Zinc was bound to soil mostly by weak electrostatic forces. Copper and Pb were bound at specific sorption sites and by complex multi-site bonding mechanisms possibly involving organic substances. These specific and multi-site mechanisms account for metal ions removed from solution at low concentration. Even at low metal concentration, Cu and Pb sorption results in concurrent release of H⁺ and Ca²⁺ at a greater than one to one charge basis.
Soils adjusted to various pH levels were equilibrated with Cu solution and then extracted with a series of dilute acid extractions to determine Cu adsorption and fixation capacities. Copper adsorption and more importantly Cu fixation increased with an increase in soil pH. Soil with a high organic matter content as a result of manure applications adsorbed and fixed more Cu at all pH levels than the control and CuSO₄ soil. The presence of organic matter may have a greater effect on metal sorption characteristics than maintenance of pH ≥ 6.5. Heavy metal sorption was accompanied by concurrent release of H⁺ and Ca²⁺ which represents exchangeable and specifically bound cation nutrients. Soils which receive heavy metal applications from sewage sludge or animal manure would have a short-term increase in plant available nutrients at the expense of long-term reserve capacity. Soil tests for cation nutrient availability on soils receiving heavy metal applications should be adopted to account for these responses. / Ph. D.
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The assessment of copper and zinc removal from highway stormwater runoff using Apatite II™Huang, Hsiao-Wen 31 May 2012 (has links)
Copper and zinc are heavy metals commonly present in highway stormwater runoff. Discharge of these metals to surface waters inhabited by sensitive aquatic species including threatened and endangered salmonids has necessitated the need for improved treatment techniques. Although copper is of the greater toxicological concern, zinc is often present at concentrations several times higher than copper and may compete with copper during adsorptive treatment processes. In the current study, the ability biogenic fish-bone based alternative adsorbent, Apatite II™, for copper and zinc removal from synthetic stormwater runoff was evaluated. Batch experiments were employed to examine equilibrium removal and rapid small scale column tests (RSSCT) were used to simulate dynamic operation in continuous systems. In both batch and continuous systems, the release of phosphate and calcium were observed, and Apatite II™ achieved high removal efficiencies. The removal of copper and zinc was likely due to a combination of processes including adsorption, ion exchange and precipitation. Precipitation played a dominant role in copper removal and the release of phosphate and pH buffering appear to drive this process. While precipitation was also quite important for zinc removal, adsorptive removal also played a role. The findings from the current study provide a general understanding of the performance of copper and zinc removal from stormwater runoff using Apatite II™. / Graduation date: 2012
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