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Current status of research on nanobubbles in particle flotation

Autorzy
Chen Jian , Chen Jun , Cheng Yali
Treść / Zawartość
Pełne teksty:
PPoMP_2024_60_1_183613.pdf
Identyfikatory
DOI
10.37190/ppmp/183613
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Froth flotation, as one of the most widely used separation approaches in mineral processing, is commonly used to recover valuable components from minerals. However, maintaining high flotation efficiencies is a serious challenge for conventional froth flotation in the face of decreasing particle size of the minerals to be sorted. To date, there have been plenty of reports on the software of nano-bubbles (NBS) in flotation, and the experimental consequences show that nano-bubbles' introduction has given rise to improvement's different grades in the recovery of varieties of minerals, which highlights the great potential of nano-bubbles for mineral flotation. Nanobubbles have smaller bubble radii and unusually high stability compared to conventional flotation bubbles, and their related behavior in flotation has been a hot research topic. This paper reviews some of the methods of preparing nanobubbles, equipment techniques for characterizing nanobubbles, factors affecting their stability, and some of the popular doctrines. In particular, the reinforcing mechanism of nanobubbles in the particle flotation process is discussed, first, the nanobubbles improve the electrostatic attractiveness with the particles by achieving the charge inversion while the nanobubbles that was adsorbed on the particles' surface will cover a share of the charge, which decreases the electrostatic repulsive force between the particles; and second, the nanobubbles can act as a bridge between the surfaces of the two particles, which advances the agglomeration between the particles. This review aims to be able to further advance the research related to the industrialization of nanobubbles.
Słowa kluczowe
EN
Wydawca
Oficyna Wydawnicza Politechniki Wrocławskiej
Czasopismo
Physicochemical Problems of Mineral Processing
Rocznik
2024
Tom
Vol. 60, iss. 1
Strony
art. no. 183613
Opis fizyczny
Bibliogr. 150 poz., rys., wykr.
Twórcy
autor
Chen Jian
  • Department of Materials Science and Engineering, Anhui University of Science and Technology, Huainan 232001, China
autor
Chen Jun
jchen412@126.com
  • Department of Materials Science and Engineering, Anhui University of Science and Technology, Huainan 232001, China
autor
Cheng Yali
  • Department of Materials Science and Engineering, Anhui University of Science and Technology, Huainan 232001, China
Bibliografia
  • ABENOJAR, E. C., BEDERMAN, I., DE LEON, A. C., ZHU, J., HADLEY, J., KOLIOS, M. C. and EXNER, A. A., 2020, Theoretical and Experimental Gas Volume Quantification of Micro- and Nanobubble Ultrasound Contrast Agents, Pharmaceutics, 123, 208.
  • AGARWAL, K., TRIVEDI, M. and NIRMALKAR, N., 2022, Does salting-out effect nucleate nanobubbles in water: Spontaneous nucleation?, Ultrasonics Sonochemistry, 82, 105860.
  • AHMADI, R., KHODADADI, D. A., ABDOLLAHY, M. and FAN, M., 2014, Nano-microbubble flotation of fine and ultrafine chalcopyrite particles, International Journal of Mining Science and Technology, 244, 559-566.
  • ALAM, H. S., SUTIKNO, P., SOELAIMAN, T. A. F. and SUGIARTO, A. T., 2022, Bulk Nanobubbles: generation using a two-chamber swirling flow nozzle and long-term stability in water, Journal of Flow Chemistry, 122, 161-173.
  • ATTARD, P., 2003, Nanobubbles and the hydrophobic attraction, Advances in Colloid and Interface Science, 1041-3, 75-91.
  • AZADI, M., NGUYEN, A. V. and YAKUBOV, G. E., 2020, The Effect of Dissolved Gases on the Short-Range Attractive Force between Hydrophobic Surfaces in the Absence of Nanobubble Bridging, Langmuir, 3634, 9987-9992.
  • AZEVEDO, A., ETCHEPARE, R., CALGAROTO, S. and RUBIO, J., 2016, Aqueous dispersions of nanobubbles: Generation, properties and features, Minerals Engineering, 94, 29-37.
  • BATCHELOR, D. V. B., ARMISTEAD, F. J., INGRAM, N., PEYMAN, S. A., MCLAUGHLAN, J. R., COLETTA, P. L. and EVANS, S. D., 2021, Nanobubbles for therapeutic delivery: Production, stability and current prospects, Current Opinion in Colloid & Interface Science, 54, 101456.
  • BHATTACHARJEE, S., 2016, DLS and zeta potential – What they are and what they are not?, Journal of Controlled Release, 235, 337-351.
  • BINNIG, G., QUATE, C. F. and GERBER, C., 1986, Atomic Force Microscope, Physical Review Letters, 569, 930-933.
  • BIRD, E. and LIANG, Z., 2023, Nanobubble-Induced Aggregation of Ultrafine Particles: A Molecular Dynamics Study, Langmuir, 3928, 9744-9756.
  • BLOCK, S., FAST, B. J., LUNDGREN, A., ZHDANOV, V. P. and HööK, F., 2016, Two-dimensional flow nanometry of biological nanoparticles for accurate determination of their size and emission intensity, Nature Communications, 71, 12956.
  • BRENNER, M. P. and LOHSE, D., 2008, Dynamic Equilibrium Mechanism for Surface Nanobubble Stabilization, Physical Review Letters, 10121, 214505.
  • BU, X., ZHOU, S., TIAN, X., NI, C., NAZARI:, S. and ALHESHIBRI, M., 2022, Effect of aging time, airflow rate, and nonionic surfactants on the surface tension of bulk nanobubbles water, Journal of Molecular Liquids, 359, 119274.
  • BUI, T. T., NGUYEN, D. C. and HAN, M., 2019, Average size and zeta potential of nanobubbles in different reagent solutions, Journal of Nanoparticle Research, 218, 173.
  • CALGAROTO, S., AZEVEDO, A. and RUBIO, J., 2015, Flotation of quartz particles assisted by nanobubbles, International Journal of Mineral Processing, 137, 64-70.
  • CALGAROTO, S., AZEVEDO, A. and RUBIO, J., 2016, Separation of amine-insoluble species by flotation with nano and microbubbles, Minerals Engineering, 89, 24-29.
  • CALGAROTO, S., WILBERG, K. Q. and RUBIO, J., 2014, On the nanobubbles interfacial properties and future applications in flotation, Minerals Engineering, 60, 33-40.
  • CHANG, G., XING, Y., ZHANG, F., YANG, Z., LIU, X. and GUI, X., 2020, Effect of Nanobubbles on the Flotation Performance of Oxidized Coal, ACS Omega, 532, 20283-20290.
  • CHEN, G., REN, L., ZHANG, Y. and BAO, S., 2022, Improvement of fine muscovite flotation through nanobubble pretreatment and its mechanism, Minerals Engineering, 189, 107868.
  • CHEN, Y., CHELGANI, S. C., BU, X. and XIE, G., 2021, Effect of the ultrasonic standing wave frequency on the attractive mineralization for fine coal particle flotation, Ultrasonics Sonochemistry, 77, 105682.
  • CHO, S.-H., KIM, J.-Y., CHUN, J.-H. and KIM, J.-D., 2005, Ultrasonic formation of nanobubbles and their zeta-potentials in aqueous electrolyte and surfactant solutions, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2691, 28-34.
  • CHONGLIANG, T., FANGYUAN, M., TINGYU, W., DI, Z., YE, W., TONGLIN, Z., ZHAOLIN, F. and XINYUE, L., 2023, Study on surface physical and chemical mechanism of nanobubble enhanced flotation of fine graphite, Journal of Industrial and Engineering Chemistry, 122, 389-396.
  • CUI, X., SHI, C., XIE, L., LIU, J. and ZENG, H., 2016, Probing Interactions between Air Bubble and Hydrophobic Polymer Surface: Impact of Solution Salinity and Interfacial Nanobubbles, Langmuir, 3243, 11236-11244.
  • DING, S., XING, Y., ZHENG, X., ZHANG, Y., CAO, Y. and GUI, X., 2020, New Insights into the Role of Surface Nanobubbles in Bubble-Particle Detachment, Langmuir, 3616, 4339-4346.
  • DOCKAR, D., GIBELLI, L. and BORG, M. K., 2020, Forced oscillation dynamics of surface nanobubbles, The Journal of Chemical Physics, 15318, 184705.
  • DRAGOVIC, R. A., GARDINER, C., BROOKS, A. S., TANNETTA, D. S., FERGUSON, D. J. P., HOLE, P., CARR, B., REDMAN, C. W. G., HARRIS, A. L., DOBSON, P. J., HARRISON, P. and SARGENT, I. L., 2011, Sizing and phenotyping of cellular vesicles using Nanoparticle Tracking Analysis, Nanomedicine: Nanotechnology, Biology and Medicine, 76, 780-788.
  • DUCKER, W. A., 2009, Contact Angle and Stability of Interfacial Nanobubbles, Langmuir, 2516, 8907-8910.
  • EPSTEIN, P. S. and PLESSET, M. S., 1950, On the Stability of Gas Bubbles in Liquid-Gas Solutions, The Journal of Chemical Physics, 1811, 1505-1509.
  • ETCHEPARE, R., AZEVEDO, A., CALGAROTO, S. and RUBIO, J., 2017a, Removal of ferric hydroxide by flotation with micro and nanobubbles, Separation and Purification Technology, 184, 347-353.
  • ETCHEPARE, R., OLIVEIRA, H., NICKNIG, M., AZEVEDO, A. and RUBIO, J., 2017b, Nanobubbles: Generation using a multiphase pump, properties and features in flotation, Minerals Engineering, 112, 19-26.
  • FAN, M. and TAO, D., 2008, A Study on Picobubble Enhanced Coarse Phosphate Froth Flotation, Separation Science and Technology, 431, 1-10.
  • FAN, M., TAO, D., HONAKER, R. and LUO, Z., 2010a, Nanobubble generation and its application in froth flotation (part I): nanobubble generation and its effects on properties of microbubble and millimeter scale bubble solutions, Mining Science and Technology (China), 201, 1-19.
  • FAN, M., TAO, D., HONAKER, R. and LUO, Z., 2010b, Nanobubble generation and its applications in froth flotation (part II): fundamental study and theoretical analysis, Mining Science and Technology (China), 202, 159-177.
  • FAN, M., TAO, D., HONAKER, R. and LUO, Z., 2010c, Nanobubble generation and its applications in froth flotation (part III): Specially designed laboratory scale column flotation of phosphate, Mining Science and Technology (China), 203, 317-338.
  • FAN, M., TAO, D., HONAKER, R. and LUO, Z., 2010d, Nanobubble generation and its applications in froth flotation (part IV): Mechanical cells and specially designed column flotation of coal, Mining Science and Technology (China), 205, 641-671.
  • FARID, Z., ABDENNOURI, M., BARKA, N. and SADIQ, M. H., 2022, Grade-recovery beneficing and optimization of the froth flotation process of a mid-low phosphate ore using a mixed soybean and sunflower oil as a collector, Applied Surface Science Advances, 11, 100287.
  • FERRARO, G., JADHAV, A. J. and BARIGOU, M., 2020, A Henry's law method for generating bulk nanobubbles, Nanoscale, 1229, 15869-15879.
  • FU, H.-M., PENG, M.-W., YAN, P., WEI, Z., FANG, F., GUO, J.-S. and CHEN, Y.-P., 2021, Potential role of nanobubbles in dynamically modulating the structure and stability of anammox granular sludge within biological nitrogen removal process, Science of The Total Environment, 784, 147110.
  • GONZáLEZ-TOVAR, E. and LOZADA-CASSOU, M., 2019, Long-range forces and charge inversions in model charged colloidal dispersions at finite concentration, Advances in Colloid and Interface Science, 270, 54-72.
  • GROSS, J., SAYLE, S., KAROW, A. R., BAKOWSKY, U. and GARIDEL, P., 2016, Nanoparticle tracking analysis of particle size and concentration detection in suspensions of polymer and protein samples: Influence of experimental and data evaluation parameters, European Journal of Pharmaceutics and Biopharmaceutics, 104, 30-41.
  • GURUNG, A., DAHL, O. and JANSSON, K., 2016, The fundamental phenomena of nanobubbles and their behavior in wastewater treatment technologies, Geosystem Engineering, 193, 133-142.
  • HAMPTON, M. A. and AGGREGATES CHARACTERIZATIONS OF THE ULTRA-FINE COAL PARTICLES INDUCED BY NANOBUBBLES, A. V., 2010, Nanobubbles and the nanobubble bridging capillary force, Advances in Colloid and Interface Science, 1541-2, 30-55.
  • HAMPTON, M. A., DONOSE, B. C. and NGUYEN, A. V., 2008, Effect of alcohol–water exchange and surface scanning on nanobubbles and the attraction between hydrophobic surfaces, Journal of Colloid and Interface Science, 3251, 267-274.
  • HAMPTON, M. A. and NGUYEN, A. V., 2009, Systematically altering the hydrophobic nanobubble bridging capillary force from attractive to repulsive, Journal of Colloid and Interface Science, 3332, 800-806.
  • HAN, H., LIU, A. and WANG, H., 2020, Effect of Hydrodynamic Cavitation Assistance on Different Stages of Coal Flotation, Minerals, 103, 221.
  • HAN, M. Y., 2002, Modeling of DAF: the effect of particle and bubble characteristics, Journal of Water Supply: Research and Technology-Aqua, 511, 27-34.
  • HAN, M. Y., AHN, H. J., SHIN, M. S. and KIM, S. R., 2004, The effect of divalent metal ions on the zeta potential of bubbles, Water Science and Technology, 508, 49-56.
  • HAN, M. Y., KIM, M. K. and AHN, H. J., 2006, Effects of surface charge, micro-bubble size and particle size on removal efficiency of electro-flotation, Water Science and Technology, 537, 127-132.
  • HASSANZADEH, A., HASSAS, B. V., KOUACHI, S., BRABCOVA, Z. and ÇELIK, M. S., 2016, Effect of bubble size and velocity on collision efficiency in chalcopyrite flotation, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 498, 258-267.
  • ISHIDA, N., INOUE, T., MIYAHARA, M. and HIGASHITANI, K., 2000, Nano Bubbles on a Hydrophobic Surface in Water Observed by Tapping-Mode Atomic Force Microscopy, Langmuir, 1616, 6377-6380.
  • JALILI, N. and LAXMINARAYANA, K., 2004, A review of atomic force microscopy imaging systems: application to molecular metrology and biological sciences, Mechatronics, 148, 907-945.
  • JIN, J., WANG, R., TANG, J., YANG, L., FENG, Z., XU, C., YANG, F. and GU, N., 2020, Dynamic tracking of bulk nanobubbles from microbubbles shrinkage to collapse, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 589, 124430.
  • KIM, J.-Y., SONG, M.-G. and KIM, J.-D., 2000, Zeta Potential of Nanobubbles Generated by Ultrasonication in Aqueous Alkyl Polyglycoside Solutions, Journal of Colloid and Interface Science, 2232, 285-291.
  • KIOKA, A. and NAKAGAWA, M., 2021, Theoretical and experimental perspectives in utilizing nanobubbles as inhibitors of corrosion and scale in geothermal power plant, Renewable and Sustainable Energy Reviews, 149, 111373.
  • KNüPFER, P., DITSCHERLEIN, L. and PEUKER, U. A., 2017, Nanobubble enhanced agglomeration of hydrophobic powders, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 530, 117-123.
  • KYZAS, G. Z., MITROPOULOS, A. C. and MATIS, K. A., 2021, From Microbubbles to Nanobubbles: Effect on Flotation, Processes, 98, 1287.
  • LABARRE, L. A., SAINT-JALMES, A. and VIGOLO, D., 2022, Microfluidics investigation of the effect of bulk nanobubbles on surfactant-stabilised foams, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 654, 130169.
  • LEVITSKY, I., TAVOR, D. and GITIS, V., 2022, Micro and nanobubbles in water and wastewater treatment: A state-of-theart review, Journal of Water Process Engineering, 47, 102688.
  • LI, C., 2023, Fluidized-bed flotation of coarse molybdenite particles: matching mechanism for bubble and particle sizes, Separation and Purification Technology, 324, 124592.
  • LI, C., LI, X., XU, M. and ZHANG, H., 2020a, Effect of ultrasonication on the flotation of fine graphite particles: Nanobubbles or not?, Ultrasonics Sonochemistry, 69, 105243.
  • LI, C., XU, M., XING, Y., ZHANG, H. and PEUKER, U. A., 2020b, Efficient separation of fine coal assisted by surface nanobubbles, Separation and Purification Technology, 249, 117163.
  • LI, C., XU, M. and ZHANG, H., 2022a, The interactions between coal particles with different hydrophobicity and bulk nanobubbles in natural water, International Journal of Coal Preparation and Utilization, 423, 463-474.
  • LI, C. and ZHANG, H., 2022b, Surface nanobubbles and their roles in flotation of fine particles – A review, Journal of Industrial and Engineering Chemistry, 106, 37-51.
  • LI, M., LIU, J., LI, J., XIANG, B., MANICA, R. and LIU, Q., 2022c, Enhancement of selective fine particle flotation by microbubbles generated through hydrodynamic cavitation, Powder Technology, 405, 117502.
  • LI, M., MA, X., EISENER, J., PFEIFFER, P., OHL, C.-D. and SUN, C., 2021, How bulk nanobubbles are stable over a wide range of temperatures, Journal of Colloid and Interface Science, 596, 184-198.
  • LI, P., ZHANG, M., YAO, W., XU, Z. and FAN, R., 2022d, Effective Separation of High-Ash Fine Coal Using Water Containing Positively Charged Nanobubbles and Polyaluminum Chloride, ACS Omega, 72, 2210-2216.
  • LIU, H. and CAO, G., 2016, Effectiveness of the Young-Laplace equation at nanoscale, Scientific Reports, 61, 23936.
  • LIU, L., HU, S., WU, C., LIU, K., WENG, L. and ZHOU, W., 2021, Aggregates characterizations of the ultra-fine coal particles induced by nanobubbles, Fuel, 297, 120765.
  • LIU, Y. and ZHANG, X., 2014, A unified mechanism for the stability of surface nanobubbles: Contact line pinning and supersaturation, The Journal of Chemical Physics, 14113, 134702.
  • LOHSE, D. and ZHANG, X., 2015, Surface nanobubbles and nanodroplets, Reviews of Modern Physics, 873, 981-1035.
  • LOU, S.-T., OUYANG, Z.-Q., ZHANG, Y., LI, X.-J., HU, J., LI, M.-Q. and YANG, F.-J., 2000, Nanobubbles on solid surface imaged by atomic force microscopy, Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena, 185, 2573-2575.
  • LU, Y., 2019, Drag reduction by nanobubble clusters as affected by surface wettability and flow velocity: Molecular dynamics simulation, Tribology International, 137, 267-273.
  • MA, F. and TAO, D., 2022, A Study of Mechanisms of Nanobubble-Enhanced Flotation of Graphite, Nanomaterials, 1219, 3361.
  • MA, F., TAO, D. and TAO, Y., 2022a, Effects of nanobubbles in column flotation of Chinese sub-bituminous coal, International Journal of Coal Preparation and Utilization, 424, 1126-1142.
  • MA, X., LI, M., PFEIFFER, P., EISENER, J., OHL, C.-D. and SUN, C., 2022b, Ion adsorption stabilizes bulk nanobubbles, Journal of Colloid and Interface Science, 606, 1380-1394.
  • MA, Y., GUO, Z., CHEN, Q. and ZHANG, X., 2021, Dynamic Equilibrium Model for Surface Nanobubbles in Electrochemistry, Langmuir, 378, 2771-2779.
  • MICHAILIDI, E. D., BOMIS, G., VAROUTOGLOU, A., KYZAS, G. Z., MITRIKAS, G., MITROPOULOS, A. C., EFTHIMIADOU, E. K. and FAVVAS, E. P., 2020, Bulk nanobubbles: Production and investigation of their formation/stability mechanism, Journal of Colloid and Interface Science, 564, 371-380.
  • MIETTINEN, T., RALSTON, J. and FORNASIERO, D., 2010, The limits of fine particle flotation, Minerals Engineering, 235, 420-437.
  • MIKHLIN, Y., KARACHAROV, A., VOROBYEV, S., ROMANCHENKO, A., LIKHATSKI, M., ANTSIFEROVA, S. and MARKOSYAN, S., 2020, Towards Understanding the Role of Surface Gas Nanostructures: Effect of Temperature Difference Pretreatment on Wetting and Flotation of Sulfide Minerals and Pb-Zn Ore, Nanomaterials, 107, 1362.
  • NAZARI, S. and HASSANZADEH, A., 2020, The effect of reagent type on generating bulk sub-micron (nano) bubbles and flotation kinetics of coarse-sized quartz particles, Powder Technology, 374, 160-171.
  • NAZARI, S., LI, J., KHOSHDAST, H., LI, J., YE, C., HE, Y. and HASSANZADEH, A., 2023, Effect of roasting pretreatment on micro-nanobubble-assisted flotation of spent lithium-ion batteries, Journal of Materials Research and Technology, 24, 2113-2128.
  • NAZARI, S., ZHOU, S., HASSANZADEH, A., LI, J., HE, Y., BU, X. and KOWALCZUK, P. B., 2022, Influence of operating parameters on nanobubble-assisted flotation of graphite, Journal of Materials Research and Technology, 20, 3891-3904.
  • NIRMALKAR, N., PACEK, A. W. and BARIGOU, M., 2018a, Interpreting the interfacial and colloidal stability of bulk nanobubbles, Soft Matter, 1447, 9643-9656.
  • NIRMALKAR, N., PACEK, A. W. and BARIGOU, M., 2018b, On the Existence and Stability of Bulk Nanobubbles, Langmuir, 3437, 10964-10973.
  • OLIVEIRA, H., AZEVEDO, A. and RUBIO, J., 2018, Nanobubbles generation in a high-rate hydrodynamic cavitation tube, Minerals Engineering, 116, 32-34.
  • OLIVEIRA, H. A., AZEVEDO, A. C., ETCHEPARE, R. and RUBIO, J., 2017, Separation of emulsified crude oil in saline water by flotation with micro- and nanobubbles generated by a multiphase pump, Water Science and Technology, 7610, 2710-2718.
  • OLSZOK, V., RIVAS-BOTERO, J., WOLLMANN, A., BENKER, B. and WEBER, A. P., 2020, Particle-induced nanobubble generation for material-selective nanoparticle flotation, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 592, 124576.
  • OWENS, C. L., SCHACH, E., HEINIG, T., RUDOLPH, M. and NASH, G. R., 2019, Surface nanobubbles on the rare earth fluorcarbonate mineral synchysite, Journal of Colloid and Interface Science, 552, 66-71.
  • OWENS, CAMILLA L., SCHACH, E., RUDOLPH, M. and NASH, G. R., 2018, Surface nanobubbles on the carbonate mineral dolomite, RSC Advances, 862, 35448-35452.
  • PANCHAL, J., KOTAREK, J., MARSZAL, E. and TOPP, E. M., 2014, Analyzing Subvisible Particles in Protein Drug Products: a Comparison of Dynamic Light Scattering (DLS) and Resonant Mass Measurement (RMM), The AAPS Journal, 163, 440-451.
  • PARKER, J. L., CLAESSON, P. M. and ATTARD, P., 1994, Bubbles, cavities, and the long-ranged attraction between hydrophobic surfaces., The Journal of Physical Chemistry, 9834, 8468-8480.
  • POURKARIMI, Z., REZAI, B., NOAPARAST, M., NGUYEN, A. V. and CHEHREH CHELGANI, S., 2021, Proving the existence of nanobubbles produced by hydrodynamic cavitation and their significant effects in powder flotation, Advanced Powder Technology, 325, 1810-1818.
  • REIS, A. S., REIS FILHO, A. M., DEMUNER, L. R. and BARROZO, M. A. S., 2019, Effect of bubble size on the performance flotation of fine particles of a low-grade Brazilian apatite ore, Powder Technology, 356, 884-891.
  • REN, L., ZHANG, Z., ZENG, W. and ZHANG, Y., 2023, Adhesion between nanobubbles and fine cassiterite particles, International Journal of Mining Science and Technology, 334, 503-509.
  • ROSA, A. F. and RUBIO, J., 2018, On the role of nanobubbles in particle–bubble adhesion for the flotation of quartz and apatitic minerals, Minerals Engineering, 127, 178-184.
  • SHADMAN, M., HOSSEINI, M. R., ZINJENAB, Z. T. and AZIMI, E., 2023, Significant reduction in collector consumption by implementing ultrafine bubbles in lead and zinc rougher flotation, Powder Technology, 414, 118096.
  • SNOSWELL, D. R. E., DUAN, J., FORNASIERO, D. and RALSTON, J., 2003, Colloid Stability and the Influence of Dissolved Gas, The Journal of Physical Chemistry B, 10713, 2986-2994.
  • SOBHY, A. and TAO, D., 2013a, High-Efficiency Nanobubble Coal Flotation, International Journal of Coal Preparation and Utilization, 335, 242-256.
  • SOBHY, A. and TAO, D., 2013b, Nanobubble column flotation of fine coal particles and associated fundamentals, International Journal of Mineral Processing, 124, 109-116.
  • SOBHY, A. and TAO, D., 2019, Effects of Nanobubbles on Froth Stability in Flotation Column, International Journal of Coal Preparation and Utilization, 394, 183-198.
  • SOBHY, A., WU, Z. and TAO, D., 2021, Statistical analysis and optimization of reverse anionic hematite flotation integrated with nanobubbles, Minerals Engineering, 163, 106799.
  • TAN, B. H., AN, H. and OHL, C.-D., 2018, Surface Nanobubbles Are Stabilized by Hydrophobic Attraction, Physical Review Letters, 12016, 164502.
  • TAO, D., 2005, Role of Bubble Size in Flotation of Coarse and Fine Particles—A Review, Separation Science and Technology, 394, 741-760.
  • TAO, D., 2022, Recent advances in fundamentals and applications of nanobubble enhanced froth flotation: A review, Minerals Engineering, 183, 107554.
  • TAO, D. and SOBHY, A., 2019, Nanobubble effects on hydrodynamic interactions between particles and bubbles, Powder Technology, 346, 385-395.
  • TAO, D., WU, Z. and SOBHY, A., 2021, Investigation of nanobubble enhanced reverse anionic flotation of hematite and associated mechanisms, Powder Technology, 379, 12-25.
  • THI PHAN, K. K., TRUONG, T., WANG, Y. and BHANDARI, B., 2020, Nanobubbles: Fundamental characteristics and applications in food processing, Trends in Food Science & Technology, 95, 118-130.
  • USHIKUBO, F. Y., FURUKAWA, T., NAKAGAWA, R., ENARI, M., MAKINO, Y., KAWAGOE, Y., SHIINA, T. and OSHITA, S., 2010, Evidence of the existence and the stability of nano-bubbles in water, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 3611-3, 31-37.
  • WANG, B. and PENG, Y., 2014, The effect of saline water on mineral flotation – A critical review, Minerals Engineering, 66-68, 13-24.
  • WANG, H., YANG, W., YAN, X., WANG, L., WANG, Y. and ZHANG, H., 2020, Regulation of bubble size in flotation: A review, Journal of Environmental Chemical Engineering, 85, 104070.
  • WANG, Q., ZHAO, H., QI, N., QIN, Y., ZHANG, X. and LI, Y., 2019a, Generation and Stability of Size-Adjustable Bulk Nanobubbles Based on Periodic Pressure Change, Scientific Reports, 91, 1118.
  • WANG, X., YUAN, S., LIU, J., ZHU, Y. and HAN, Y., 2022, Nanobubble-enhanced flotation of ultrafine molybdenite and the associated mechanism, Journal of Molecular Liquids, 346, 118312.
  • WANG, Y., PAN, Z., LUO, X., QIN, W. and JIAO, F., 2019b, Effect of nanobubbles on adsorption of sodium oleate on calcite surface, Minerals Engineering, 133, 127-137.
  • WARD, C. A., TIKUISIS, P. and VENTER, R. D., 1983, THE STABILITY OF GAS BUBBLES IN LIQUID-GAS SOLUTIONS, Annals of the New York Academy of Sciences, 4041 Fourth Intern, 455-455.
  • WEIJS, J. H. and LOHSE, D., 2013, Why Surface Nanobubbles Live for Hours, Physical Review Letters, 1105, 054501.
  • WEPENER, D. A., LE ROUX, J. D. and CRAIG, I. K., 2023, Extremum seeking control to optimize mineral recovery of a flotation circuit using peak air recovery, Journal of Process Control, 129, 103033.
  • WU, J., ZHANG, K., CEN, C., WU, X., MAO, R. and ZHENG, Y., 2021, Role of bulk nanobubbles in removing organic pollutants in wastewater treatment, AMB Express, 111, 96.
  • WU, L., HAN, Y., ZHANG, Q. and ZHAO, S., 2019, Effect of external electric field on nanobubbles at the surface of hydrophobic particles during air flotation, RSC Advances, 94, 1792-1798.
  • WU, Z., TAO, D., TAO, Y. and MA, G., 2023, New insights into mechanisms of pyrite flotation enhancement by hydrodynamic cavitation nanobubbles, Minerals Engineering, 201, 108222.
  • XIA, Y., WANG, L., ZHANG, R., YANG, Z., XING, Y., GUI, X., CAO, Y. and SUN, W., 2019, Enhancement of flotation response of fine low-rank coal using positively charged microbubbles, Fuel, 245, 505-513.
  • XIAO, Q., LIU, Y., GUO, Z., LIU, Z., LOHSE, D. and ZHANG, X., 2017, Solvent Exchange Leading to Nanobubble Nucleation: A Molecular Dynamics Study, Langmuir, 3332, 8090-8096.
  • XIAO, W., KE, S., QUAN, N., ZHOU, L., WANG, J., ZHANG, L., DONG, Y., QIN, W., QIU, G. and HU, J., 2018, The Role of Nanobubbles in the Precipitation and Recovery of Organic-Phosphine-Containing Beneficiation Wastewater, Langmuir, 3421, 6217-6224.
  • XIAO, W., WANG, X., ZHOU, L., ZHOU, W., WANG, J., QIN, W., QIU, G., HU, J. and ZHANG, L., 2019a, Influence of Mixing and Nanosolids on the Formation of Nanobubbles, The Journal of Physical Chemistry B, 1231, 317-323.
  • XIAO, W., ZHAO, Y., YANG, J., REN, Y., YANG, W., HUANG, X. and ZHANG, L., 2019b, Effect of Sodium Oleate on the Adsorption Morphology and Mechanism of Nanobubbles on the Mica Surface, Langmuir, 3528, 9239-9245.
  • XIE, L., GONG, L., ZHANG, J., HAN, L., XIANG, L., CHEN, J., LIU, J., YAN, B. and ZENG, H., 2019, A wet adhesion strategy via synergistic cation–π and hydrogen bonding interactions of antifouling zwitterions and mussel-inspired binding moieties, Journal of Materials Chemistry A, 738, 21944-21952.
  • XU, C., PENG, S., QIAO, G. G., GUTOWSKI, V., LOHSE, D. and ZHANG, X., 2014, Nanobubble formation on a warmer substrate, Soft Matter, 1039, 7857-7864.
  • YASUDA, K., MATSUSHIMA, H. and ASAKURA, Y., 2019, Generation and reduction of bulk nanobubbles by ultrasonic irradiation, Chemical Engineering Science, 195, 455-461.
  • YASUI, K., TUZIUTI, T., KANEMATSU, W. and KATO, K., 2015, Advanced dynamic-equilibrium model for a nanobubble and a micropancake on a hydrophobic or hydrophilic surface, Physical Review E, 913, 033008.
  • ZHANG, F., SUN, L., YANG, H., GUI, X., SCHöNHERR, H., KAPPL, M., CAO, Y. and XING, Y., 2021a, Recent advances for understanding the role of nanobubbles in particles flotation, Advances in Colloid and Interface Science, 291, 102403.
  • ZHANG, F., XING, Y., CHANG, G., YANG, Z., CAO, Y. and GUI, X., 2021b, Enhanced lignite flotation using interfacial nanobubbles based on temperature difference method, Fuel, 293, 120313.
  • ZHANG, J. and ZENG, H., 2021, Intermolecular and Surface Interactions in Engineering Processes, Engineering, 71, 63-83.
  • ZHANG, M., CAO, S., LIU, A., CORNELISSEN, J. J. L. M. and LEMAY, S. G., 2020a, Self-Assembly of Viral Capsid Proteins Driven by Compressible Nanobubbles, The Journal of Physical Chemistry Letters, 1124, 10421-10424.
  • ZHANG, M., LI, P., YAO, W., XU, Z. and FAN, R., 2022, Enhanced kaolinite flotation using amine coated nanobubbles, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 638, 128296.
  • ZHANG, M. and SEDDON, J. R. T., 2016, Nanobubble–Nanoparticle Interactions in Bulk Solutions, Langmuir, 3243, 11280-11286.
  • ZHANG, M., SEDDON, J. R. T. and LEMAY, S. G., 2019, Nanoparticle–nanobubble interactions: Charge inversion and re-entrant condensation of amidine latex nanoparticles driven by bulk nanobubbles, Journal of Colloid and Interface Science, 538, 605-610.
  • ZHANG, X.-Y., WANG, Q.-S., WU, Z.-X. and TAO, D.-P., 2020b, An experimental study on size distribution and zeta potential of bulk cavitation nanobubbles, International Journal of Minerals, Metallurgy and Materials, 272, 152-161.
  • ZHANG, X., CHAN, D. Y. C., WANG, D. and MAEDA, N., 2013, Stability of Interfacial Nanobubbles, Langmuir, 294, 1017-1023.
  • ZHANG, X. H., KHAN, A. and DUCKER, W. A., 2007, A Nanoscale Gas State, Physical Review Letters, 9813, 136101.
  • ZHANG, X. H., MAEDA, N. and CRAIG, V. S. J., 2006, Physical Properties of Nanobubbles on Hydrophobic Surfaces in Water and Aqueous Solutions, Langmuir, 2211, 5025-5035.
  • ZHANG, X. H., QUINN, A. and DUCKER, W. A., 2008, Nanobubbles at the Interface between Water and a Hydrophobic Solid, Langmuir, 249, 4756-4764.
  • ZHANG, Z., REN, L. and ZHANG, Y., 2021c, Role of nanobubbles in the flotation of fine rutile particles, Minerals Engineering, 172, 107140.
  • ZHANG, Z., WEI, Q., JIAO, F. and QIN, W., 2023, Role of nanobubbles on the fine lepidolite flotation with mixed cationic/anionic collector, Powder Technology, 427, 118785.
  • ZHOU, S., BU, X., WANG, X., NI, C., MA, G., SUN, Y., XIE, G., BILAL, M., ALHESHIBRI, M., HASSANZADEH, A. and CHELGANI, S. C., 2022a, Effects of surface roughness on the hydrophilic particles-air bubble attachment, Journal of Materials Research and Technology, 18, 3884-3893.
  • ZHOU, S., NAZARI, S., HASSANZADEH, A., BU, X., NI, C., PENG, Y., XIE, G. and HE, Y., 2022b, The effect of preparation time and aeration rate on the properties of bulk micro-nanobubble water using hydrodynamic cavitation, Ultrasonics Sonochemistry, 84, 105965.
  • ZHOU, S., WANG, X., BU, X., WANG, M., AN, B., SHAO, H., NI, C., PENG, Y. and XIE, G., 2020a, A novel flotation technique combining carrier flotation and cavitation bubbles to enhance separation efficiency of ultra-fine particles, Ultrasonics Sonochemistry, 64, 105005.
  • ZHOU, W., CHEN, H., OU, L. and SHI, Q., 2016, Aggregation of ultra-fine scheelite particles induced by hydrodynamic cavitation, International Journal of Mineral Processing, 157, 236-240.
  • ZHOU, W., NIU, J., XIAO, W. and OU, L., 2019, Adsorption of bulk nanobubbles on the chemically surface-modified muscovite minerals, Ultrasonics Sonochemistry, 51, 31-39.
  • ZHOU, W., WU, C., LV, H., ZHAO, B., LIU, K. and OU, L., 2020b, Nanobubbles heterogeneous nucleation induced by temperature rise and its influence on minerals flotation, Applied Surface Science, 508, 145282.
  • ZOUBOULIS, A. I., KYDROS, K. A. and MATIS, K. A., 1992, Adsorbing Flotation of Copper Hydroxo Precipitates by Pyrite Fines, Separation Science and Technology, 2715, 2143-2155.
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