A comprehensive study of the leaching behavior and dissolution kinetics of copper oxide ore in sulfuric acid lixiviant

Azizi, Asghar; Bayati, Behrooz; Karamoozian, Mohammad

doi:10.24200/sci.2018.5226.1154

Cited by 11 publications

(6 citation statements)

References 33 publications

(44 reference statements)

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“…Therefore, it can be concluded that the activation energy (9.8 kJ/mol) of the first leaching stage described the Cu dissolution in hydroxide form with sulfuric acid, following the ash diffusion model. This model was reported previously for the sulfuric acid-assisted Cu leaching from oxide ores containing the Cu 2 (OH) 2 •CO 3 phase [25,26]. However, the obtained activation energy was higher than that of the present work, 20.6 kJ/mol [25], and 26.69 kJ/mol [26].…”

Section: Mechanism Of Cu Leaching From Waste Sludge In Sulfuric Acidsupporting

confidence: 79%

“…This model was reported previously for the sulfuric acid-assisted Cu leaching from oxide ores containing the Cu 2 (OH) 2 •CO 3 phase [25,26]. However, the obtained activation energy was higher than that of the present work, 20.6 kJ/mol [25], and 26.69 kJ/mol [26]. The difference was attributed to the higher content of Ca (16.7%) and SiO 2 (37.04 to 69.2%) in the copper ores, compared to that of the copper sludge (Ca 6.24%, SiO 2 0%), the latter being able to precipitate on the surface of the sample particle during leaching.…”

Section: Mechanism Of Cu Leaching From Waste Sludge In Sulfuric Acidsupporting

confidence: 56%

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Selective Copper Recovery by Acid Leaching from Printed Circuit Board Waste Sludge

Trinh

Kim

Lee

2020

Metals

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The most challenging issue associated with recycling the sludge generated from printed circuit boards (PCBs) is the separation of copper (Cu) from iron (Fe), using multi-stage leaching, or adding oxidizing and precipitating agents. Herein we investigated simple acid leaching to effectively extract copper and limit iron dissolution. Selective copper leaching was achieved with all the acids studied, including HCl, HNO3, and H2SO4. The lower concentration of acid solutions resulted in a larger difference in leachabilities between Cu and Fe. Among three leachates, the H2SO4 solution performed effectively on the selective leaching of Cu and Fe. Adjusting the pulp density to 4% and the H2SO4 concentration at ~0.2 M, accomplished ~95% Cu leaching and reduced the Fe extraction to less than 5%. Kinetic studies revealed that Cu leaching followed the ash diffusion-controlled mechanism. Aactivation energy (Ea) of 9.8 kJ/mol was determined for the first 10 min of leaching. Further, leaching up to 60 min corresponded to a mixed control model, increasing the Ea to 20.9 kJ/mol. The change in the control model with regard to the two leaching stages can be attributed to the Cu hydroxide and metal phases present in the original sample. A simple, economically attractive H2SO4 acid leaching process was demonstrated, recovering Cu efficiently and selectively from PCBs waste sludge under moderate conditions.

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Section: Mechanism Of Cu Leaching From Waste Sludge In Sulfuric Acidsupporting

confidence: 79%

Section: Mechanism Of Cu Leaching From Waste Sludge In Sulfuric Acidsupporting

confidence: 56%

Selective Copper Recovery by Acid Leaching from Printed Circuit Board Waste Sludge

Trinh

Kim

Lee

2020

Metals

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“…The authors claimed that the shrinking core model complies with the obtained leaching kinetic experimental data. Using a 13% sulfuric acid concentration, stirring speed of 600 rpm, liquid/solid ratio of 10 mL/g, and 50 o C as reaction temperature, Azizi et al [17] managed to dissolve about 91% copper content after 80 min leaching time. The dissolution kinetics was examined according to heterogeneous models and found that the dissolution of copper in sulfuric acid solution is controlled by the diffusion through the product layer considering the shrinking core model to be appropriate enough to describe the leaching process.…”

Section: Previous Studiesmentioning

confidence: 99%

“…The average activation energy of copper leaching from low-grade cuprite ores was determined to be 45.28 kJ mol-1 by Bai et al [16]. Azizi et al [17] estimated a value of 26.699 kJ/mole for the dissolution kinetics of copper oxide ore in sulfuric acid. In their study, Tanaydin and Demirkiran [18] reported an activation energy value of 34.69 kJ/mole for the leaching kinetics of malachite in perchloric acid solutions.…”

Section: Effect Of Temperature On Ks and Dmentioning

confidence: 99%

Kinetics of Hydrochloric Acid Leaching of Copper from its Ore

2020

IJETER

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The effects of some experimental parameters on the copper leaching process were investigated and presented in a previous article, while in the current article kinetic models to represent the effects of leaching temperature, acid concentration, and ore particle size on the leaching rate will be examined and analyzed. The obtained results showed that none of the surface chemical reaction or the pore diffusion on its own can control the whole copper dissolution process. The mixed kinetics model which includes two different leaching processes including the surface chemical reaction and diffusion through a porous product layer was found to be suitable for describing and fitting the experimental data up to 65 % copper dissolution (X) at a high stirring speed of 1000 rpm. The apparent activation energies for pore diffusion and surface reaction were estimated to be 12.26 and 9.61 kcal/mol, respectively. Values of surface reaction rate constant in the range from 6.35´10 -4 to 5.49´10 -3 cm/sec and pore diffusion coefficient in the range from 3.58´10 -8 to 2.36´10 -7 cm 2 /sec have been obtained.

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“…Alloys of Copper have the immense capability for usage in a variety of industrial sectors including marine systems, construction, transportation, for encapsulating material wastages especially nuclear wastes etc and this usage is possible mainly because of their 2 superior thermal and electrical conductivities, a unique combination of ductility and strength, exemplary resistance to corrosion etc [1][2][3][4][5] Even though there exists an everlasting demand for the alloys of copper (Cu) in several industrial sectors, the usage of these alloys are restricted due to the difficulty in welding them [6][7][8][9]. Fusion-based joining techniques are not suitable for copper, as the existence of pernicious and eruptive constituents such as zinc (present in the alloys of Cu) and other oxides (adherent in nature) deteriorate the quality of weld [10][11][12][13]. In addition to this, the peculiar characteristic features of alloys of Cu namely, larger level of thermal diffusivity, elevated oxidation rate, etc also hinder the successful welding of alloys of Cu by fusion-based joining techniques [14,15].…”

Section: Introductionmentioning

confidence: 99%

Impact of speed of traverse during joining of CDA101 plates by FSW process

Kumar¹,

Sevvel²

2022

Scientia Iranica

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An experimental investigation was carried out to comprehend the impact of speed of traverse of tool on tensile strength and micro-structural peculiarities of attained joints during friction stir welding of Cu alloy namely CDA 101 flat plates, with other parameters namely spinning speed of tool (1100 rpm) and downward force (6kN) being constant. A tool with cylindrical tapered pin geometry was made to traverse at distinctive speeds from 20 mm/min to 45 mm/min. It was observed that, the CDA 101 joints fabricated at 20 mm/min was found to be entirely free flaws, with joints fabricated at other speeds of tool traverse possessing several weld flaws. Grains in the center of the zone of stir of the joints obtained at 20 mm/min was uniformly distributed and homogeneous, due to the experience of the exemplary volume of frictional heat and sufficient amount of stirring force. Highest tensile strength of 200.65 MPa (nearly 85.38% of base metal)was exhibited by joint attained at 20 mm/min.

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A comprehensive study of the leaching behavior and dissolution kinetics of copper oxide ore in sulfuric acid lixiviant

Cited by 11 publications

References 33 publications

Selective Copper Recovery by Acid Leaching from Printed Circuit Board Waste Sludge

Selective Copper Recovery by Acid Leaching from Printed Circuit Board Waste Sludge

Kinetics of Hydrochloric Acid Leaching of Copper from its Ore

Impact of speed of traverse during joining of CDA101 plates by FSW process

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