Anodic oxidation of cuprous sulphide in aqueous solutions

Fraser, Michael J.

January 1965

The oxidation of artificial cuprous sulphide electrodes (Cu/S ratio = 1.93) was studied in acidified copper sulphate solutions in the temperature range 20 to 35° C. Rest potential measurements gave V° = 0.490 volts for the electrode or half cell potential. This is within the limits of accuracy of V° for: Cu₂S —CuS + Cu⁺⁺ + 2e V° = 0.535 + 0.13 volts The discrepancy was thought to be related to the large Cu deficien in the sulphide. In solutions with pH>4, the rest potential measurements were consistent with the following reaction: Cu₂S + 2H₂0 —CuS + Cu(OH)₂ + 2H⁺ + 2e Polarization measurements at low overpotential gave values for the following kinetic parameters: β, the symmetry factor = 1/2 λ, the number of electrons involved in each act of the rate determining step = 2 i₀, the exchange current ≈ 2 x 10-⁵ A/cm² ΔH₀*, the standard heat of activation = 26.5 kcal/mole CuS was tentatively identified as one of the reaction products. A reaction mechanism was discussed. / Applied Science, Faculty of / Materials Engineering, Department of / Graduate

Electrolytic oxidation

Cuprous sulphide

Application of electrochemical kinetics to elucidate the leaching mechanism in the bio-oxidation of a synthetic nickel sulphide

Huberts, Robert

06 February 2015

The importance of the direct and indirect mechanisms in the bacterial leaching of a synthetic nickel sulphide is investigated using an electrochemical leaching model. Sterile controls runs, in which only ferric leaching took place, are compared with runs in the presence of an active, adapted bacterial culture. The direct mechanism occurs when bacteria attach to the sulphide mineral and catalyze the oxidation of the mineral, presumably with enzymes (biological catalysts). No evidence was found of the direct mechanism, in fact ferric leaching appeared to be inhibited as the bacterial presence increased due to growth. Considering evidence obtained by the fitting of the electrochemical model, it is tentatively suggested that leaching of the mineral is largely due to chemical ferric leaching, with the leaching role of bacteria restricted to re-oxidizing the resulting ferrous ions. Whether this is the case for other minerals remains to be established.

Nickel sulphide

Leaching

Surface photo-oxidation and metal film growth processes on amorphous GeS←2

Horton, Joseph Hugh

January 1994

No description available.

530.41

Microbially influenced corrosion (MIC) of steels in mono- and hyper-baric environments

Sutton, Jeremy

January 1994

No description available.

620.11223

Sulphide corrosion; Anaerobic corrosion

Influence of mineralogy on biohydrometallurgical processing of complex sulphide ore

Olubambi, Peter Apata

28 January 2009

The mineralogical basis for understanding biohydrometallurgical processing of low-grade sulphide ores and means by which microwave processing improves their microbial recovery is investigated using a Nigerian low-grade complex sulphide ore as a case study. The study is approached through an applied mineralogical study of the ore and its influence on developing an optimal route for the microbial leaching of the low-grade complex ore under varying process parameters, and an investigation on the interaction between mineralogy, microwave processing and bioleaching. Bioleaching behaviour, mechanisms of bioleaching, and the interplay of mineralogy and microwave irradiation and their influence on bioleaching process were carried out using mixed cultures of Thiobacillus ferrooxidans, Thiobacillus thiooxidans and Leptospirillium ferrooxidans in a mechanically stirred glass reactor at varying bioleaching process parameters and through electrochemical studies. Mineralogical analysis of the ore revealed the presence of siderite, sphalerite, galena, quartz, and traces of pyrite and chalcopyrite, with the ore exhibiting fine to coarse grain intergrowths of the constituent crystalline phases both at the interstitials and the boundaries. Complexity in the mineralogy of the ore affected mineralogical and elemental distribution amongst varying size fractions that led to variation in the galvanic behaviour within these size fractions and influenced microbe-mineral’s reactivity and the different dissolutions behaviours. Bioleaching at optimal bioleaching parameters revealed the highest dissolution at a particle size fraction of 75 μm, while electrochemical studies revealed the highest dissolution at particle size fraction of 106 μm. This discrepancy was consistent with and attributed both to the physical and mineralogical influences. The combined effects of mineralogical variation, precipitation phenomenon as well as the physico-chemical effect of particle size, controlled bioleaching behaviour, while galvanic interaction resulting from variations in mineralogical distribution controlled the electrochemical behaviour. Ore mineralogy and microwave heating both showed dual influences on heating characteristics, size reduction, and the effectiveness of microwave treatment in improving dissolution. The increase in the dissolution rate and the overall dissolution of the microwave treated samples is attributed to phase changes in the ore which promoted galvanic interaction within the system, decrease in the amounts of sulphur contents, and an increase in electrochemical and microbial growth sites resulting from an increase in the number of cracks induced by microwave heating.

Some studies of the tendering of sulfur black dyed cotton

Zimmerman, Charles Loos

05 1900

No description available.

Sulphide dyes

Dyes and dyeing Cotton

Application of sulfur dyes on cotton at high temperature

Murauskas, William Arthur

January 1954

No description available.

Dyes and dyeing Cotton

Sulphide dyes

Electrochemical concentration of H[subscript]2S from coal gas

Lim, Hyun Sung

12 1900

No description available.

Electrochemical analysis

Electrochemistry

Hydrogen sulphide

Chemical beam epitaxial growth of (001) ZnS

Shen, Xiu-Li

08 1900

No description available.

Molecular beam epitaxy

Zinc sulphide

The reactivity of iron and zinc sulfide mineral surfaces :

Weisener, Christopher G.

Unknown Date

Thesis (PhDMiningEngineering)--University of South Australia, 2001.

Sulphide minerals.

Sulphur mines and mining