王超等：浮选过程中颗粒-气泡黏附作用机理及研究进展 ·1433· effects in flotation.Part I:microscale experimental observations. (2):1517 Miner Eng,2014,58:80 [67]Albijanic B,Ozdemir O,Hampton M A,et al.Fundamental as- [53]Brabcovi Z,Karapantsios T,Kostoglou M,et al.Bubble-particle pects of bubble-particle attachment mechanism in flotation separa- collision interaction in flotation systems.Colloids Surf A,2015, tion.Miner Eng,2014,65:187 473:95 [68]Tabor R F,Grieser F,Dagastine RR,et al.Measurement and [54]Verrelli D I,Koh PT L,Nguyen A V.Particle-bubble interac- analysis of forces in bubble and droplet systems using AFM.J tion and attachment in flotation.Chem Eng Sci,2011,66(23): Colloid Interface Sci,2012,317(1):1 5910 [69]Ejtemaei M,Nguyen A V.A comparative study of the attachment [55]Zawala J,Kosior D.Dynamics of dewetting and bubble attach- of air bubbles onto sphalerite and pyrite surfaces activated by cop- ment to rough hydrophobic surfaces-Measurements and model- per sulphate.Miner Eng,2017,109:14 ling.Miner Eng,2016,85:112 [70]Ejtemaei M,Nguyen A V.Kinetic studies of amyl xanthate ad- [56]Kosior D.Zawala J,Krasowska M,et al.Influence of n-octanol sorption and bubble attachment to Cu-activated sphalerite and py- and a-terpineol on thin film stability and bubble attachment to rite surfaces.Miner Eng,2017,112:36 hydrophobic surface.Phys Chem Chem Phys,2013,15 (7): [71]Sun W,Hu Y H,Dai J P,et al.Observation of fine particle ag- 2586 gregating behavior induced by high intensity conditioning using [57]Del Castillo L A,Ohnishi S,Carnie S L,et al.Variation of local high speed CCD.Trans Nonferrous Met Soc China,2006,16 surface properties of an air bubble in water caused by its interac- (1):198 tion with another surface.Langmuir,2016,32(30):7671 [72]Ren L Y,Zhang Y M,Qin W Q,et al.Collision and attachment [58]Gui X H,Xing Y W,Rong G Q,et al.Interaction forces be- behavior between fine cassiterite particles and H bubbles.Trans tween coal and kaolinite particles measured by atomic force mi- Nonferrous Met Soc China,2014,24(2):520 croscopy.Pouder Technol,2016,301:349 [73]Wang W X,Zhou Z A,Nandakumar K,et al.Attachment of in- [59]Pan J N,Zhu H T,Hou Q L,et al.Macromolecular and pore dividual particles to a stationary air bubble in model systems.Int structures of Chinese tectonically deformed coal studied by atomic J Miner Process,2003,68(1-4):47 force microscopy.Fuel,2015,139:94 [74]Spyridopoulos M T,Simons S J R.Direct measurement of bub- [60]Yu X K,Burnham N A,Tao M J.Surface microstructure of bitu- ble-particle adhesion forces on the effects of particle hydrophobic- men characterized by atomic force microscopy.Ad Colloid Inter. ity and surfactants.Chem Eng Res Des,2004,82(4):490 face Sci,2015,218:17 [75]Xing Y W,Gui X H,Cao Y J.Effect of bubble size on bubble- [61]Yin X H,Gupta V,Du H,et al.Surface charge and wetting particle attachment and film drainage kinetics-A theoretical study. characteristics of layered silicate minerals.Adv Colloid Interface Pouder Technol,2017,322:140 Sci,2012,179-182:43 [76]Nguyen A V,Evans G M.Attachment interaction between air [62]Yan LJ,Masliyah J H,Xu Z H.Understanding suspension rhe- bubbles and particles in froth flotation.Exp Therm Fluid Sci, ology of anisotropically-charged platy minerals from direct interac- 2004,28(5):381 tion force measurement using AFM.Curr Opin Colloid Interface [77]Feng D X.Nguyen A V.How does the Gibbs inequality condi- Si,2013,18(2):149 tion affect the stability and detachment of floating spheres from [63]Yang DZ,Xie L,Bobicki E,et al.Probing anisotropic surface the free surface of water?Langmuir,2016,32(8):1988 properties and interaction forees of chrysotile rods by atomic force [78]Feng D X,Nguyen A V.Contact angle variation on single float- microscopy and rheology.Langmuir,2014,30(36):10809 ing spheres and its impact on the stability analysis of floating par- [64]Lu ZZ,Liu Q X,Xu Z H,et al.Probing anisotropic surface ticles.Colloids Surf A,2017,520:442 properties of molybdenite by direet force measurements.Lang- [79]Xu D,Ametov I,Grano S R.Detachment of coarse particles from muir,2015,31(42):11409 oscillating bubbles-the effect of particle contact angle,shape [65]Rudolph M,Peuker U A.Mapping hydrophobicity combining and medium viscosity.Int Miner Process,2011,101(14):50 AFM and Raman spectroscopy.Miner Eng,2014,66-68:181 [80]Fosu S,Skinner W,Zanin M.Detachment of coarse composite [66]Xing Y W,Gui X H,Cao Y J.Effect of calcium ion on coal flo- sphalerite particles from bubbles in flotation:influence of xan- tation in the presence of kaolinite clay.Energy Fuels,2016.30 thate collector type and concentration.Miner Eng,2015,71:73王 超等: 浮选过程中颗粒鄄鄄气泡黏附作用机理及研究进展 effects in flotation. Part 1: microscale experimental observations. Miner Eng, 2014, 58: 80 [53] Brabcov觃 Z, Karapantsios T, Kostoglou M, et al. Bubble鄄particle collision interaction in flotation systems. Colloids Surf A, 2015, 473: 95 [54] Verrelli D I, Koh P T L, Nguyen A V. Particle鄄bubble interac鄄 tion and attachment in flotation. Chem Eng Sci, 2011, 66(23): 5910 [55] Zawala J, Kosior D. Dynamics of dewetting and bubble attach鄄 ment to rough hydrophobic surfaces鄄 Measurements and model鄄 ling. Miner Eng, 2016, 85: 112 [56] Kosior D, Zawala J, Krasowska M, et al. Influence of n鄄octanol and 琢鄄terpineol on thin film stability and bubble attachment to hydrophobic surface. Phys Chem Chem Phys, 2013, 15 ( 7 ): 2586 [57] Del Castillo L A, Ohnishi S, Carnie S L, et al. Variation of local surface properties of an air bubble in water caused by its interac鄄 tion with another surface. Langmuir, 2016, 32(30): 7671 [58] Gui X H, Xing Y W, Rong G Q, et al. Interaction forces be鄄 tween coal and kaolinite particles measured by atomic force mi鄄 croscopy. Powder Technol, 2016, 301: 349 [59] Pan J N, Zhu H T, Hou Q L, et al. Macromolecular and pore structures of Chinese tectonically deformed coal studied by atomic force microscopy. Fuel, 2015, 139: 94 [60] Yu X K, Burnham N A, Tao M J. Surface microstructure of bitu鄄 men characterized by atomic force microscopy. Adv Colloid Inter鄄 face Sci, 2015, 218: 17 [61] Yin X H, Gupta V, Du H, et al. Surface charge and wetting characteristics of layered silicate minerals. Adv Colloid Interface Sci, 2012, 179鄄182: 43 [62] Yan L J, Masliyah J H, Xu Z H. Understanding suspension rhe鄄 ology of anisotropically鄄charged platy minerals from direct interac鄄 tion force measurement using AFM. Curr Opin Colloid Interface Sci, 2013, 18(2): 149 [63] Yang D Z, Xie L, Bobicki E, et al. Probing anisotropic surface properties and interaction forces of chrysotile rods by atomic force microscopy and rheology. Langmuir, 2014, 30(36): 10809 [64] Lu Z Z, Liu Q X, Xu Z H, et al. Probing anisotropic surface properties of molybdenite by direct force measurements. Lang鄄 muir, 2015, 31(42): 11409 [65] Rudolph M, Peuker U A. Mapping hydrophobicity combining AFM and Raman spectroscopy. Miner Eng, 2014, 66鄄68: 181 [66] Xing Y W, Gui X H, Cao Y J. Effect of calcium ion on coal flo鄄 tation in the presence of kaolinite clay. Energy Fuels, 2016, 30 (2): 1517 [67] Albijanic B, Ozdemir O, Hampton M A, et al. Fundamental as鄄 pects of bubble鄄particle attachment mechanism in flotation separa鄄 tion. Miner Eng, 2014, 65: 187 [68] Tabor R F, Grieser F, Dagastine R R, et al. Measurement and analysis of forces in bubble and droplet systems using AFM. J Colloid Interface Sci, 2012, 317(1): 1 [69] Ejtemaei M, Nguyen A V. A comparative study of the attachment of air bubbles onto sphalerite and pyrite surfaces activated by cop鄄 per sulphate. Miner Eng, 2017, 109: 14 [70] Ejtemaei M, Nguyen A V. Kinetic studies of amyl xanthate ad鄄 sorption and bubble attachment to Cu鄄activated sphalerite and py鄄 rite surfaces. Miner Eng, 2017, 112: 36 [71] Sun W, Hu Y H, Dai J P, et al. Observation of fine particle ag鄄 gregating behavior induced by high intensity conditioning using high speed CCD. Trans Nonferrous Met Soc China, 2006, 16 (1): 198 [72] Ren L Y, Zhang Y M, Qin W Q, et al. Collision and attachment behavior between fine cassiterite particles and H2 bubbles. Trans Nonferrous Met Soc China, 2014, 24(2): 520 [73] Wang W X, Zhou Z A, Nandakumar K, et al. Attachment of in鄄 dividual particles to a stationary air bubble in model systems. Int J Miner Process, 2003, 68(1鄄4): 47 [74] Spyridopoulos M T, Simons S J R. Direct measurement of bub鄄 ble鄄particle adhesion forces on the effects of particle hydrophobic鄄 ity and surfactants. Chem Eng Res Des, 2004, 82(4): 490 [75] Xing Y W, Gui X H, Cao Y J. Effect of bubble size on bubble鄄 particle attachment and film drainage kinetics鄄A theoretical study. Powder Technol, 2017, 322: 140 [76] Nguyen A V, Evans G M. Attachment interaction between air bubbles and particles in froth flotation. Exp Therm Fluid Sci, 2004, 28(5): 381 [77] Feng D X, Nguyen A V. How does the Gibbs inequality condi鄄 tion affect the stability and detachment of floating spheres from the free surface of water? Langmuir, 2016, 32(8): 1988 [78] Feng D X, Nguyen A V. Contact angle variation on single float鄄 ing spheres and its impact on the stability analysis of floating par鄄 ticles. Colloids Surf A, 2017, 520: 442 [79] Xu D, Ametov I, Grano S R. Detachment of coarse particles from oscillating bubbles—the effect of particle contact angle, shape and medium viscosity. Int J Miner Process, 2011, 101(1鄄4): 50 [80] Fosu S, Skinner W, Zanin M. Detachment of coarse composite sphalerite particles from bubbles in flotation: influence of xan鄄 thate collector type and concentration. Miner Eng, 2015, 71: 73 ·1433·