| 1 |
Application of microwave energy in the destruction of dioxins in the froth product after flotation of hospital solid waste incinerator fly ash
Wei GX, Liu HQ, Zhang R, Zhu YW, Xu X, Zang DD
Journal of Hazardous Materials, 325, 230, 2017 |
| 2 |
Flotation frother mixtures: Decoupling the sub-processes of froth stability, froth recovery and entrainment
McFadzean B, Marozva T, Wiese J
Minerals Engineering, 85, 72, 2016 |
| 3 |
Effect of nanoparticles on froth stability and bubble size distribution in flotation
Cilek EC, Karaca S
International Journal of Mineral Processing, 138, 6, 2015 |
| 4 |
The link between froth surface grade and flotation feed grade
Hadler K
Minerals Engineering, 78, 32, 2015 |
| 5 |
The implications of the froth recovery at the laboratory scale
Amelunxen P, Sandoval G, Barriga D, Amelunxen R
Minerals Engineering, 66-68, 54, 2014 |
| 6 |
Visualization of flow in froth
Blonde P, Finch JA
Minerals Engineering, 35, 16, 2012 |
| 7 |
The use of machine vision to predict flotation performance
Morar SH, Harris MC, Bradshaw DJ
Minerals Engineering, 36-38, 31, 2012 |
| 8 |
Frothing behavior of aqueous solutions of oleic acid
Atrafi A, Gomez CO, Finch JA, Pawlik M
Minerals Engineering, 36-38, 138, 2012 |
| 9 |
The use of the froth surface lamellae burst rate as a flotation froth stability measurement
Morar SH, Bradshaw DJ, Harris MC
Minerals Engineering, 36-38, 152, 2012 |
| 10 |
The effect of froth depth on air recovery and flotation performance
Hadler K, Greyling M, Plint N, Cilliers JJ
Minerals Engineering, 36-38, 248, 2012 |
