| 1 |
Frother structure-property relationship: Effect of polyethylene glycols on bubble rise velocity
Tan YH, Zhang W, Finch JA
Minerals Engineering, 116, 56, 2018 |
| 2 |
Experience coating bubbles with solvent in a downcomer
Kuan SH, Tan YH, Finch JA
Minerals Engineering, 123, 160, 2018 |
| 3 |
Using Sound To Study the Effect of Frothers on the Breakaway of Air Bubbles at an Underwater Capillary
Chu PB, Pax R, Li RH, Langlois R, Finch JA
Langmuir, 33(13), 3200, 2017 |
| 4 |
Reducing the self-heating of sulphides by chemical treatment with lignosulfonates
Rosenblum F, Nesset JE, Moon S, Finch JA, Waters KE
Minerals Engineering, 107, 78, 2017 |
| 5 |
Passive acoustic emission monitoring to detect bubble coalescence in the presence of solid particles
Quinn JJ, Finch JA
Minerals Engineering, 108, 25, 2017 |
| 6 |
Mapping frother distribution in industrial flotation circuits
Zangooi A, Gomez CO, Finch JA
Minerals Engineering, 113, 36, 2017 |
| 7 |
Zeta potential study of pentlandite in the presence of serpentine and dissolved mineral species
Alvarez-Silva M, Uribe-Salas A, Waters KE, Finch JA
Minerals Engineering, 85, 66, 2016 |
| 8 |
Frother structure-property relationship: Effect of hydroxyl position in alcohols on bubble rise velocity
Tan YH, Finch JA
Minerals Engineering, 92, 1, 2016 |
| 9 |
Frother analysis in flotation circuits: Refinement of a colorimetric technique
Zangooi A, Gomez CO, Finch JA
Minerals Engineering, 93, 41, 2016 |
| 10 |
Frother structure-property relationship: Effect of alkyl chain length in alcohols and polyglycol ethers on bubble rise velocity
Tan YH, Finch JA
Minerals Engineering, 95, 14, 2016 |
