| 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 |
Effect of ionic strength on bubble coalescence in inorganic salt and seawater solutions
Sovechles JM, Waters KE
AIChE Journal, 61(8), 2489, 2015 |
| 3 |
Validity of critical coalescence concentration in dynamic conditions
Javor Z, Schreithofer N, Heiskanen K
International Journal of Mineral Processing, 127, 16, 2014 |
| 4 |
Determining frother-like properties of process water in bitumen flotation
Nassif M, Finch JA, Waters KE
Minerals Engineering, 56, 121, 2014 |
| 5 |
Critical coalescence concentration of inorganic salt solutions
Quinn JJ, Sovechles JM, Finch JA, Waters KE
Minerals Engineering, 58, 1, 2014 |
| 6 |
Effect of frothers on bubble coalescence and foaming in electrolyte solutions and seawater
Castro S, Miranda C, Toledo P, Laskowski JS
International Journal of Mineral Processing, 124, 8, 2013 |
| 7 |
Developing critical coalescence concentration curves for industrial process waters using dilution
Nassif M, Finch JA, Waters KE
Minerals Engineering, 50-51, 64, 2013 |
| 8 |
Study of the local critical coalescence concentration (l-CCC) of alcohols and salts at bubble formation in two-phase systems
Kracht W, Rebolledo H
Minerals Engineering, 50-51, 77, 2013 |
| 9 |
Effect of alcohol and polyglycol bubble size and ether frothers on foam stability, coal flotation
Gupta AK, Banerjee PK, Mishra A, Satish P, Pradip
International Journal of Mineral Processing, 82(3), 126, 2007 |
| 10 |
Role of frothers in bubble generation and coalescence in a mechanical flotation cell
Grau RA, Laskowski JS
Canadian Journal of Chemical Engineering, 84(2), 170, 2006 |
