The aqueous processing of minerals and materials

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31. Y. Awakura, M. Aoki, A. Tsuchiya and H. Majima, “Determination of the Diffusion Coefficients of NiCl₂, ZnCl₂, and CdCl₂ in Aqueous Solution,” Met. Trans., 20B (1989), pp. 555–565.

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36. M. Kobayashi and H. Kametani, “The Eh-pH Diagram of the Pb-S-H₂O System and its Correlation with Lattice Imperfection and Electronic Charge Carriers in PbS,” Hydrometall., 22 (1989), pp. 141–157.

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38. E. Krause and V.A. Ettel, “Solubilities and Stabilities of Ferric Arsenic Compounds,” Hydrometall, 22 (1989), pp. 311–337.

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39. Y. Zhang and M. Muhammed, “Solubility of Calcium Sulfate Dihydrate in Nitric Acid Solutions Containing Cal-cium Nitrate and Phosphoric Acid,” /. Chem. Eng. Data, 34 (1989), pp. 121–124.

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40. Proceedings, International Gold Expo (Aurora, CO: Industrial Presentations, Inc., 1989).

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42. L. White, “Gold Processing Scrutinized at Las Vegas SME Meeting,” Mining Eng., 41 (1989), pp. 435–439.

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43. P.M. Ferreira, K. Knott-Craig and D.W. Boydell, “Roasting of Refractory Au Concentrates at New Consort,” E&MJ, 190(12) (1989), pp. 26–30.

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44. G. Folland and B. Peinemann, “Lurgi’s Circulating Fluid Bed Applied to Gold Roasting,” E&MJ, 190(10) (1989), pp. 28–30.

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45. D.M. Hausen, “Processing Gold Quarry Refractory Ores,” JOM, 41(4) (1989), pp. 43–45.

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46. T.V. Subrahmanyam and K.S.E. Forssberg, “Recovery Problems in Gold Ore Processing with Emphasis on Heap Leaching,” Min. Process. & Ext. Metall. Rev., 4 (1989) 201–215.

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47. R.S. Shoemaker, “Heap and Dump Leaching of Gold Ores in the United States,” Minerals Industry Int., Bull. Inst. Min. Metall., 986 (Jan. 1989), pp. 28–29.

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48. J.A. McMaster, “CILO Process Enhances Gold Recovery,” JOM, 41(5) (1989), p. 54.

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49. A. Dadgar, “Refractory Concentrate Gold Leaching: Cyanide vs. Bromine,” JOM, 41(12) (1989), pp. 37–41.

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50. N.P. Gallagher, J.L. Hendrix and E.B. Milosavljevic, “The Affinity of Carbon for Gold Complexes: Dissolution of Finely Disseminated Gold using a Flow Electrochemical Cell,” J. Electrochem. Soc., 136 (1989), pp. 2546–2551.

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51. D.J. Millenacker, “In-Situ Mining,” E&MJ,190(9) (1989), pp. 56–58.

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52. S.S. Cook and S.E. Paulson, “Leaching Characteristics of Selected Supergene Copper Ores,” Mining Eng., 41 (1989), pp. 33–39.

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53. H. Majima, Y. Awakura, K. Enami, H. Ueshima and T. Hirato, “Kinetic Study of the Dissolution of Cuprite in Oxyacid Solutions,” Met. Trans., 20B (1989), pp. 573–580.

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54. J. Suni, H. Henein, G.W. Warren and D. Reddy, “Modelling the Leaching Kinetics of a Sphalerite Concentrate Size Distribution in Ferric Chloride Solution,” Hydrometall., 22 (1989), pp. 25–38.

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55. D.B. Dreisinger and E. Peters, “The Oxidation of Ferrous Sulphate by Molecular Oxygen Under Zinc Pressure-Leach Conditions,” Hydrometall, 22 (1989), pp. 101–119.

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56. A.N. Buckley, H.J. Wouterlood and R. Woods, “The Surface Composition of Natural Sphalerites Under Oxidative Leaching Conditions,” Hydrometall., 22 (1989), pp. 39–56.

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57. A.N. Buckley, H.J. Wouterlood and R. Woods, “The Interaction of Pyrite with Solutions Containing Silver Ions,” J. Appl. Electrochem., 19 (1989), pp. 744–751.

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58. F.M. Doyle, H. Arauco and L.M. Feng, “Iron Removal During Oxidative, Acid Pressure Leaching of a Zinc Sulphide Concentrate,” Int. J. Miner. Process., 25 (1989), pp. 241–260.

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59. M.K. Ghosh, S. Anand and R.P. Das, “Effect of Dissolved Impurities During Ammonia Leaching of Pure Zinc Sulphide,” Hydrometall., 22(1989), pp. 207–221.

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60. X. Wang, E. Forssberg and N.J. Bolin, “The Aqueous and Surface Chemistry of Activation in the Flotation of Sulphide Minerals—A Review. Part II: A Surface Precipitation Model,” Min. Process. & Ext. Metall. Rev., 4 (1989), pp. 167–199.

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62. H.Y. Sohn and H.D. Baek, “The Mixed-Control Kinetics of Ferric Chloride Leaching of Galena,” Met. Trans., 20B (1989), pp. 107–110.

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63. J.E. Dutrizac, “The Leaching of Galena in Cupric Chloride Media,” Met. Trans., 20B (1989), pp. 475–483.

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64. J.E. Dutrizac, “Sulphate Control in Chloride Leaching Processes,” Hydrometall., 23 (1989), pp. 1–22.

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65. J.E. Dutrizac, “Elemental Sulphur Formation During the Ferric Sulphate Leaching of Chalcopyrite,” Canad. Metall. Quart., 28 (1989), pp. 337–344.

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66. T. Hirato, H. Hiai, Y. Awakura and H. Majima, “The Leaching of Sintered CuS Disks with Ferric Chlorides,” Met. Trans., 20B (1989), pp. 485–491.

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67. L.K. Witika and W.C. Lombe, “Electrochemical Behaviour of Carrollite (CuCo₂S₄) in Aqueous Buffer Solutions,” Trans. Inst. Min. Metall., 98 (1989), pp. C26–C32.

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68. H. Morisaki, H. Ono and K. Yazawa, “Electronic State Densities of Aquo-Complex Ions in Water Determined by Electrochemical Tunneling Spectroscopy,” J. Electrochem. Soc., 136 (1989), pp. 1710–1714.

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69. I. Iwasaki and M.S. Prasad, “Processing Techniques for Difficult-to-Treat Ores by Combining Chemical Metallurgy and Mineral Processing,” Min. Process. & Ext. Metall. Rev., 4 (1989), pp. 241–276.

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70. N.V. Ngoc, M. Shamsuddin and P.M. Prasad, “Salt Roasting of an Off-Grade Copper Concentrate,” Hydrometall., 21 (1989), pp. 359–372.

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71. E.H. Cho, “Coal Desulfurization with Aqueous Chlorine,” Met. Trans., 20B (1989), pp. 567–571.

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72. P.G. Campbell, ed., Light Metals ’89 (Warrendale, PA: TMS, 1989).

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73. G. Patermarakis and Y. Paspaliaris, “The Leaching of Iron Oxides in Boehmitic Bauxite by Hydrochloric Acid,” Hy-drometall., 23 (1989), pp. 77–90.

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74. Y. Paspaliaris, Y. Yiouli and G. Patermarakis, “Reaction Kinetics for Leaching of Iron Oxides in Boehmitic Bauxite by Hydrochloric Acid,” Trans. Inst. Min. Metall., 98 (1989), pp. C21–C25.

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75. A.W. Kirby and D.J. Fray, “Possible Route for Chromium Production from Ferrochromium Powder—1: Nitriding,” Trans. Inst. Min. Metall., 98 (1989), pp. C33–C40.

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76. A.W. Kirby and D.J. Fray, “Possible Route for Chromium Production from Ferrochromium Powder–2: Removal of Iron from Nitrided Ferrochromium by Leaching,” Trans. Inst. Min. Metall., 98 (1989), pp. C89–C95.

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77. A.W. Kirby and D.J. Fray, “Possible Route for Chromium Production from Ferrochromium Powder—3: Dissociation Behaviour of Chromium Nitride,” Trans. Inst. Min. Metall., 98 (1989), pp. C96–C98.

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78. Yu Zhang and M. Muhammed, “The Removal of Phosphorus from Iron Ore by Leaching with Nitric Acid,” Hydrometall., 21 (1989), pp. 255–275.

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79. M. Muhammed and Y. Zhang, “A Hydrometallurgical Process for the Dephosphorization of Iron Ore,” Hydrometall., 21 (1989), pp. 277–292.

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81. R.K. Jana and D.D. Akerkar, “Studies of the Metal-Ammonia-Carbon Dioxide-Water System in Extraction Metallurgy of Polymetallic Sea Nodules,” Hydrometall., 22 (1989), pp. 363–378.

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82. Q. Song, Y. Zhao and J. Zhu, “Dephosphorization of Manganese Ore by High-Intensity Magnetic Separation and Roast-Leaching,” Trans. Inst. Min. Metall., 98 (1989), pp. C17–C20.

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83. P.K. Sahoo and K. S. Rao, “Sulphation-Roasting of Low-Grade Manganese Ores—Optimisation by Factorial Design,” Int. J. Miner. Process., 25 (1989), pp. 147–152.

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84. W. Köck and P. Paschen, “Tantalum—Processing, Properties and Applications,” JOM, 41(10) (1989), pp. 33–39.

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85. Z.I. Ozdal and R.H. Eric, “Autoclave Soda Leaching: A Case Study on Uludag Flotation Scheelite Concentrate,” Min. Process. & Ext. Metall. Rev., 4 (1989), pp. 217–240.

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86. D.A. Hansen and D.E. Traut, “The Kinetics of Leaching Rock Ilmenite with Hydrofluoric Acid,” JOM, 41(5) (1989), pp. 34–36.

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87. M. Iwai and J.M. Toguri, “The Leaching of Celestite in Sodium Carbonate Solution,” Hydrometall., 22 (1989), pp. 87–100.

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88. K.G. Tan and P.L. Bedard, “Ammonia Leach Process for the Treatment of Copper Refinery Anode Slimes Containing High Lead and Low Nickel,” Canad. Metall. Quart., 28 (1989), pp. 199–210.

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89. R.M. Morrison, “The Dissolution of Silver in Ferric Sulphate-Sulphuric Acid Media,” Hydrometall., 22 (1989), pp. 67–85.

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90. L.S.Y. Lee and F. Lawson, “The Leaching Rate of Tin Metal in Oxygenated Sodium Hydroxide Solutions,” Hydrometall., 23 (1989), pp. 23–35.

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91. B.J. Schneider, F.M. Doyle and S.K. Kawatra, eds., Biotechnology in Minerals and Metal Processing (Littleton, CO: SME, 1989).

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92. Biohydrometallurgy ’89, Jackson, WY, August 1989 (E.M.R. CANMET, U.S. Bureau of Mines and U.S. Department of Energy).

93. Second Workshop—Bacterial Leaching, Santiago, Chile, October 1989.

94. L. Toro, S. Di Cesare, B. Paponetti and A. Lepidi, “Biochemical and Chemical Events in Copper Solubilization from a Chalcopyrite Concentrate by Thiobacillus ferrooxidans in a Batch Culture,” Int. J. Miner. Process., 26 (1989), pp. 153–162.

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95. A. Ballester, F. Gonzales, M.L. Blazquez and M.A. Barril, “Microbiological Leaching of Copper from Lead Mattes,” Met. Trans., 20B (1989), pp. 773–779.

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96. N. Jyothi, K.N. Sudha and K.A. Natarajan, “Electrochemical Aspects of Selective Bioleaching of Sphalerite and Chalcopyrite from Mixed Sulphides,” Int. J. Miner. Process., 27 (1989), pp. 189–203.

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97. H.M. Lizama and I. Suzuki, “Bacterial Leaching of a Sulfide Ore by Thiobacillus ferrooxidans and Thiobacillus thiooxidans. Part II. Column Leaching Studies,” Hydrometall., 22 (1989), pp. 301–310.

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98. F. Kargi, “Mathematical Model for Microbial Oxidation of Pure Lead Sulfide by Thiobacillus ferrooxidans,” Biotechnol. & Bioeng., 34 (1989), pp. 487–493.

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100. W. Uhl, H.-J. Höne, M. Beyer and J. Klein, “Continuous Microbial Desulfurization of Coal—Application of a Multistage Slurry Reactor and Analysis of the Interaction of Microbial and Chemical Kinetics,” Biotechn. &Bioeng, 34 (1989), pp. 1341–1356.

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101. B. Pesic, D.J. Oliver and P. Wichlaez, “An Electrochemical Method of Measuring the Oxidation Rate of Ferrous to Ferric Iron with Oxygen in the Presence of Thiobacillus ferrooxidans,” Biotechnol. & Bioeng., 33 (1989), pp. 428–439.

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102. G. Roy Chaudhury, L.B. Sukla and R.P. Das, “Utilization of Low-Grade Pyrites Through Bacterial Leaching,” Int. J. Miner. Process., 26 (1989), pp. 275–284.

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103. A.P. Torma, “The Microbiological Extraction of Less Common Metals,” JOM, 41(6) (1989), pp. 32–35.

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104. K.R. Suttill, “Bio-Oxidation for Refractory Gold,” E&MJ, 190(9) (1989), pp. 31–32.

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106. J. Whitlock, “The Advantages of Biodegradation of Cyanides,” JOM, 41(12) (1989), pp. 46–47.

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