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Interaction between mineral particles during ascharite flotation process and direct force measurement using AFM

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Treść / Zawartość
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Języki publikacji
EN
Abstrakty
EN
Interaction between mineral particles during ascharite flotation was investigated by flotation, zeta potential, Derjaguin-Landau-Verwey-Overbeek (DLVO) theory, atomic force microscope (AFM) and SEM-EDS tests. Flotation results showed that the ascharite recovery decreased significantly in the presence of serpentine. In order to improve the ascharite recovery, negative charged quartz was used to limit the detrimental effect of serpentine on ascharite flotation in this research. The effect of quartz on improving ascharite recovery was attributed to the particle surface interactions. The DLVO theory was applied to study the particles interaction in the aqueous solution. The fitting curves showed that serpentine could attach to the surface of quartz easily, and quartz would be well dispersed with ascharite. Therefore, quartz can improve the ascharite flotation performance effectively by interaction between particles. Zeta potential tests showed the opposite charges on the surfaces of mineral particles, which was the basic reason leading to particles interaction. The force measurement results of AFM indicated that the attraction force existed between serpentine and ascharite, as well as serpentine and quartz, but the force between quartz and ascharite was repulsive. The DLVO theory was in a good agreement with the results of AFM. Eventually, particles coating were observed by SEM-EDS, which supported the results of DLVO theory and AFM measurements. During the flotation process, addition of quartz would lead to attachment of serpentine to the quartz surface, so the adverse effect of serpentine on decreasing floatability of ascharite was weakened.
Słowa kluczowe
Rocznik
Strony
1161--1174
Opis fizyczny
Bibliogr. 34 poz., rys., tab.
Twórcy
autor
  • College of Resources and Civil Engineering, Northeastern University, Shenyang110819,China
autor
  • College of Resources and Civil Engineering, Northeastern University, Shenyang110819,China
autor
  • College of Resources and Civil Engineering, Northeastern University, Shenyang110819,China
autor
  • College of Resources and Civil Engineering, Northeastern University, Shenyang110819,China
Bibliografia
  • ALVAREZ-SILVA M., URIBE-SALAS A., WATERS K.E., FINCH J.A., 2016, Zeta potential study of pentlandite in the presence of serpentine and dissolved mineral species, Minerals Engineering, 85, 66-71.
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  • BREMMELL K.E., FORNASIERO D., RALSTON J. 2005, Pentlandite-lizardite interactions and implications for their separation by flotation, Colloids and Surfaces A-physicochemical and Engineering Aspects, 252(2/3), 207-212.
  • BROWNE C., TABOR R.F., GRIESER F., DAGASTINE R.R., 2015, Direct AFM force measurements between air bubbles in aqueous polydisperse sodium poly(styrene sulfonate) solutions: Effect of collision speed, polyelectrolyte concentration and molar mass, Journal of Colloid and Interface Science, 449, 236-245.
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  • FENG B., LU Y., LUO X., 2015, The effect of quartz on the flotation of pyrite depressed by serpentine, Journal of Materials Research and Technology, 4(1),8-13.
  • FENG B., FENG Q., LU Y., 2012, A novel method to limit the detrimental effect of serpentine on the flotation of pentlandite, International Journal of Mineral Processing, 114, 11-13.
  • FENG B., LU Y., FENG Q., ZHANG M., GU Y., 2012, Talc-serpentine interactions and implications for talc depression, Minerals Engineering,32, 68-73.
  • GALLIOS G.P., DELIYANNI E.A., PELEKA E.N., MATIS K.A., 2007, Flotation of chromite and serpentine, Separation and Purification Technology, 55,232-237.
  • Gao, Z., Hu, Y., Sun, W., & Drelich, J. W., 2016, Surface-charge anisotropy of scheelite crystals. Langmuir, 32(25), 6282-6288.
  • GAUDIN A.M., FUERSTENAU D.W., MIAW H.L., 1960, Slime coatings in galena flotation, Transactions of the Institution of Mining and Metallurgy, 63,668-671.
  • GUI X., XING Y., RONG G., CAO Y., LIU J., 2016, Interaction forces between coal and kaolinite particles measured by atomic force microscopy, Powder Technology, 301, 349-355.
  • GUPTA V., HAMPTON M.A., STOKES J.R., NGUYEN A.V., MILLER J.D., 2011, Particles interactions in kaolinite suspensions and corresponding aggregate structures, Journal of Colloid and Interface Science,359, 95-103.
  • GUPTA V., MILLER J.D., 2010, Surface force measurements at the basal planes of ordered kaolinite particles, Journal of Colloid and Interface Science, 344, 362-371.
  • HOLUSZKO M.E., FRANZIDIS J.P., MANLAPIG E.V., HAMPTON M.A., DONNOSE B.C., NGUYEN A.V., 2008, The effect of surface treatment and slime coatings on ZnS hydrophobicity, Minerals Engineering, 21, 958–966.
  • KARAMATH J.R., ADRIANA VALLEJO-CARDONA A., CERON-CAMACHO R., ZAPATA-PANASCO I.N., GARIBAY-FEBELS V., ABURTO J., 2015, Relative performance of several surfactants used for heavy crude oil emulsions as studied by AFM and force spectroscopy, Journal of Petroleum Science and Engineering, 135, 652-659.
  • KIRIJAVAINEN V., HEISKANEN K., 2007, Some factors that affect beneficiation of sulphide nickel-copper ores, Minerals Engineering, 20(7), 629-633.
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  • KUSUMA A.M., LIU Q., ZENG H., 2014, Understanding interaction mechanisms between pentlandite and gangue minerals by zeta potential and surface force measurements, Minerals Engineering, 69, 15-23.
  • LEIRO J.A., TORHOLA M., LAAJALEHTO K., 2017, The AFM method in studies of muscovite mica and galena surfaces, Journal of Physics and Chemistry Solids, 100, 40-44.
  • LI Y., HAN Y., ZHU Y., 2007, Study on the characteristic of camsellite flotation, Journal of Northeastern University (Natural Science), 28(7), 1041-1044.
  • LU Y., ZHANG M., FENG Q., LONG T., OU L., ZHANG G., 2011, Effect of sodium hexametaphosphate on separation of serpentine form pyrite, Transactions of Nonferrous Metals Society of China, 21,208-213.
  • LU J. YUAN Z., LIU J., LI L., ZHU S., 2015, Effects of magnetite on magnetic coating behavior in pentlandite and serpentine system, Minerals Engineering, 72,115-120.
  • QIN S., YIN B., ZHANG Y., ZHANG Y., 2015, Leaching kinetics of szaibelyite ore in NaOH solution, Hydrometallurgy, 157, 333-339.
  • SINHA P., SZILAGYI I., RUIZ-CABELLO F.J.M., MARONI P., BORKOVEC M., 2013, Attractive forces between charged colloidal particles induced by multivalent ions revealed by confronting aggregation and direct force measurements, Journal of Physical and Chemistry Letters, 4,648-652.
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  • WANG J., LI J., XIE L., SHI C., LIU Q., ZENG H., 2016, Interactions between elemental selenium and hydrophilic/hydrophobic surfaces: Direct force measurements using AFM, Chemical Engineering Journal, 303, 646-654.
  • WANG C., WANG H., GU G., FU J., LIN Q., LIU Y.,2015, interfacial interactions between plastic particles in plastics flotation, Waste Management, 46, 56-61.
  • XING Y., GUI X., CAO Y., 2016, Effect of Calcium Ion on Coal Flotation in the Presence of Kaolinite Clay, Energy & Fuels, 30, 1517-1523.
  • YIN X., GUPTA V., DU H., WANG X., MILLER J.D., 2012, Surface charge and wetting characteristics of layered silicate minerals, Advances in Colloid and Interface Science, 179, 43-50.
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Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-df852b64-3fd0-4d6f-8d54-205f2016812f
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