| 1 - 1 |
Froth Flotation Foreword
Brito-Parada P |
| 2 - 14 |
Evolution of flotation chemistry and chemicals: A century of innovations and the lingering challenges
Nagaraj DR, Farinato RS |
| 15 - 19 |
Break-up in formation of small bubbles: Comparison between low and high frother concentrations
Chu PB, Waters KE, Finch JA |
| 20 - 25 |
Gas dispersion properties of collector/frother blends
Zhou X, Jordens A, Cappuccitti F, Finch JA, Waters KE |
| 26 - 32 |
Gas holdup estimation in flotation machines using image techniques and superficial gas velocity
Vinnett L, Ledezma T, Alvarez-Silva M, Waters K |
| 33 - 38 |
Frother structure-property relationship: Aliphatic alcohols and bubble rise velocity
Tan YH, Finch JA |
| 39 - 45 |
Investigation of the interactive effects of the reagent suite in froth flotation of a Merensky ore
Moimane TM, Corin KC, Wiese JG |
| 46 - 52 |
Investigating the effects of particle shape on chromite entrainment at a platinum concentrator
Little L, Wiese J, Becker M, Mainza A, Ross V |
| 53 - 58 |
The entrainment effect on the performance of iron ore reverse flotation
Lima NP, Pinto TCD, Tavares AC, Sweet J |
| 59 - 66 |
Behaviour of swelling clays versus non-swelling clays in flotation
Farrokhpay S, Ndlovu B, Bradshaw D |
| 67 - 72 |
A model system for the investigation of rare earth collector interaction
Cui JL, Hope GA |
| 73 - 82 |
Xanthate-functional temperature-responsive polymers as selective flocculants and collectors for fines recovery
Ng WS, Connal LA, Forbes E, Franks GV |
| 83 - 93 |
Effect of Mg2+ and Ca2+ as divalent seawater cations on the floatability of molybdenite and chalcopyrite
Hirajima T, Suyantara GPW, Ichikawa O, Elmahdy AM, Miki H, Sasaki K |
| 94 - 98 |
A study of the reprocessing of fine and ultrafine cassiterite from gravity tailing residues by using various flotation techniques
Leistner T, Embrechts M, Leissner T, Chelgani SC, Osbahr I, Mockel R, Peuker UA, Rudolph M |
| 99 - 107 |
The influence of electrolytes present in process water on the flotation behaviour of a Cu-Ni containing ore
Manono MS, Corin KC, Wiese JG |
| 108 - 112 |
The role of cations in copper flotation in the presence of bentonite
Wang YH, Peng YJ, Nicholson T, Lauten RA |
| 113 - 122 |
The depression of copper-activated pyrite in flotation by biopolymers with different compositions
Mu YF, Peng YJ, Lauten RA |
| 123 - 129 |
The effect of biopolymer dispersants on copper flotation in the presence of kaolinite
Wang YH, Lauten RA, Peng YJ |
| 130 - 134 |
Inverse gas chromatography analysis of minerals: Pyrite wettability
Mohammadi-Jam S, Waters KE |
| 135 - 142 |
The interaction of sodium mercaptobenzothiazole with gold electrode and nanorod surfaces
Zhang K, Hope GA, Buckley AN, Li HH |
| 143 - 156 |
The depression of pyrite in selective flotation by different reagent systems - A Literature review
Mu YF, Peng YJ, Lauten RA |
| 157 - 167 |
A strategy for the identification of optimal flotation circuits
Calisaya DA, Lopez-Valdivieso A, de la Cruz MH, Galvez EE, Cisternas LA |
| 168 - 176 |
Development and calibration of a dynamic flotation circuit model
Seppala P, Sorsa A, Paavola M, Ruuska J, Remes A, Kumar H, Lamberg P, Leiviska K |
| 177 - 184 |
Classification of the Major Copper Sulphides into semiconductor types, and associated flotation characteristics
Lotter NO, Bradshaw DJ, Barnes AR |
| 185 - 193 |
Process mineralogy as a predictive tool for flowsheet design to advance the Kamoa project
Whiteman E, Lotter NO, Amos SR |
| 194 - 202 |
Improving flotation energy efficiency by optimizing cell hydrodynamics
Tabosa E, Runge K, Hoitham P, Duffy K |
| 203 - 214 |
Comparison of flash and column flotation performance in an industrial sulphide rougher application
Newcombe B |
