| 1 - 1 |
Preface
Brito-Parada P |
| 2 - 12 |
Modern practice of laboratory flotation testing for flowsheet development - A review
Lotter NO, Whiteman E, Bradshaw DJ |
| 13 - 24 |
The effect of saline water on mineral flotation - A critical review
Wang B, Peng YJ |
| 25 - 32 |
Cyanide chemistry and its effect on mineral flotation
Guo B, Peng YJ, Espinosa-Gomez R |
| 33 - 39 |
Potash flotation practice for carnallite resources in the Qinghai Province, PRC
Wang XM, Miller JD, Cheng FQ, Cheng HG |
| 40 - 46 |
Froth transport characterization in a two-dimensional flotation cell
Rojas I, Vinnett L, Yianatos J, Iriarte V |
| 47 - 53 |
Influence of particles on the formation of bubbles from a submerged capillary
Ata S, Ng KY, Law E, Lim M |
| 54 - 61 |
The implications of the froth recovery at the laboratory scale
Amelunxen P, Sandoval G, Barriga D, Amelunxen R |
| 62 - 67 |
A new small-scale test to determine flotation performance - Part 1: Overall performance
Vos CF, Stange W, Bradshaw DJ |
| 68 - 76 |
Modelling flotation with a flexible approach - Integrating different models to the compartment model
dos Santos NA, Savassi O, Peres AEC, Martins AH |
| 77 - 83 |
Distributed flotation kinetics models - A new implementation approach for coal flotation
Ofori P, O'Brien G, Hapugoda P, Firth B |
| 84 - 93 |
Measuring turbulence in a flotation cell using the piezoelectric sensor
Meng J, Xie WG, Brennan M, Runge K, Bradshaw D |
| 94 - 101 |
Fluidized bed desliming in fine particle flotation - Part III flotation of difficult to clean coal
Galvin KP, Harvey NG, Dickinson JE |
| 102 - 111 |
Selective flotation of chalcopyrite and molybdenite with plasma pre-treatment
Hirajima T, Mori M, Ichikawa O, Sasaki K, Miki H, Farahat M, Sawada M |
| 112 - 118 |
Surface energy of minerals - Applications to flotation
Mohammadi-Jam S, Burnett DJ, Waters KE |
| 119 - 129 |
Surface chemistry considerations in the flotation of bastnasite
Jordens A, Marion C, Kuzmina O, Waters KE |
| 130 - 134 |
Investigating froth stability: A comparative study of ionic strength and frother dosage
Corin KC, Wiese JG |
| 135 - 144 |
Synergetic effect of a mixture of anionic and nonionic reagents: Ca mineral contrast separation by flotation at neutral pH
Filippova IV, Filippov LO, Duverger A, Severov VV |
| 145 - 151 |
Effect of saline water on the flotation of fine and coarse coal particles in the presence of clay minerals
Wang B, Peng YJ, Vink S |
| 152 - 156 |
Effect of electrolytes on the flotation of copper minerals in the presence of clay minerals
Zhao SL, Peng YJ |
| 157 - 164 |
The effect of particle breakage mechanisms during regrinding on the subsequent cleaner flotation
Chen XM, Peng YJ, Bradshaw D |
| 165 - 172 |
Importance of oxidation during regrinding of rougher flotation concentrates with a high content of sulfides
Chen XM, Seaman D, Peng YJ, Bradshaw D |
| 173 - 180 |
Synthesis of 2-ethyl-2-hexenal oxime and its flotation performance for copper ore
Xu HF, Zhong H, Wang S, Niu YN, Liu GY |
| 181 - 190 |
Mapping hydrophobicity combining AFM and Raman spectroscopy
Rudolph M, Peuker UA |
| 191 - 196 |
Bank profiling and separation efficiency
Singh N, Finch JA |
| 197 - 201 |
Pyrite recovery mechanisms in rougher flotation circuits
Yianatos J, Carrasco C, Vinnett L, Rojas I |
| 202 - 206 |
On the collection of valuable minerals along rougher flotation banks
Yianatos J, Bergh L, Vinnett L, Rojas I |
| 207 - 214 |
Flotation separation of copper sulphides from arsenic minerals at Rosebery copper concentrator
Long G, Peng YJ, Bradshaw D |
| 215 - 220 |
Implementation of regrind-flotation pre-treatment of the CIL feed in a copper-gold plant
Burns F, Seaman D, Peng YJ, Bradshaw D |
| 221 - 229 |
Optimisation of air rate and froth depth in flotation using a CCRD factorial design - PGM case study
Venkatesan L, Harris A, Greyling M |
| 230 - 233 |
The collision efficiency of small bubbles with large particles
Basarova P, Hubicka M |
