New insights into the flotation responses of brucite and serpentine for different conditioning times: Surface dissolution behavior

Ya-feng Fu; Wan-zhong Yin; Xian-shu Dong; Chuan-yao Sun; Bin Yang; Jin Yao; Hong-liang Li; Chuang Li; Hyunjung Kim

doi:10.1007/s12613-020-2158-1

International Journal of Minerals, Metallurgy, and Materials ›› 2021, Vol. 28 ›› Issue (12) : 1898 -1907. DOI: 10.1007/s12613-020-2158-1

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New insights into the flotation responses of brucite and serpentine for different conditioning times: Surface dissolution behavior

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Abstract

The inadvertent dissolution of gangue minerals is frequently detrimental to the flotation of valuable minerals. We investigated the effect of conditioning time on the separation of brucite and serpentine by flotation. By analyzing the Mg²⁺ concentration, relative element content, and pulp viscosity, we studied the effect of mineral dissolution on brucite flotation. The results of artificially mixed mineral flotation tests (with −10 µm serpentine) showed that by extending the conditioning time from 60 to 360 s, a large amount of Mg²⁺ on the mineral surface gradually dissolved into the pulp, resulting in a decreased brucite recovery (from 83.83% to 76.79%) and an increased recovery of serpentine from 52.12% to 64.03%. To analyze the agglomeration behavior of brucite and serpentine, we used scanning electron microscopy, which clearly showed the different adhesion behaviors of different conditioning times. Lastly, the total interaction energy, as determined based on the extended DLVO (Derjaguin-Landau-Verwey-Overbeek) theory, also supports the conclusion that the gravitational force between brucite and serpentine increases significantly with increased conditioning time.

Keywords

surface dissolution / flotation / brucite / serpentine / entrainment / E-DLVO theory

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Ya-feng Fu, Wan-zhong Yin, Xian-shu Dong, Chuan-yao Sun, Bin Yang, Jin Yao, Hong-liang Li, Chuang Li, Hyunjung Kim. New insights into the flotation responses of brucite and serpentine for different conditioning times: Surface dissolution behavior. International Journal of Minerals, Metallurgy, and Materials, 2021, 28(12): 1898-1907 DOI:10.1007/s12613-020-2158-1

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References

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[1]	Blawert C, Dietzel W, Ghali E, Song G. Anodizing treatments for magnesium alloys and their effect on corrosion resistance in various environments. Adv. Eng. Mater., 2006, 8(6): 511.

[2]	Pushkaryova GI. Effect of temperature treatment of brucite on its sorption properties. J. Min. Sci., 2000, 36(6): 599.

[3]	Kusuma AM, Liu QX, Zeng HB. Understanding interaction mechanisms between pentlandite and gangue minerals by zeta potential and surface force measurements. Miner. Eng., 2014, 69, 15.

[4]	D.Z. Liu, G.F. Zhang, G.H. Huang, Y.W. Gao, and M.T. Wang, The flotation separation of pyrite from serpentine using lemon yellow as selective depressant, Colloids Surf. A, 581(2019), art. No. 123823.

[5]	Zhao KL, Yan W, Wang XH, Gu GH, Deng J, Zhou X, Hui B. Dispersive effect of low molecular weight sodium polyacrylate on pyrite-serpentine flotation system. Physicochem. Probl. Miner. Process., 2017, 53(2): 1200.

[6]	Edwards CR, Kipkie WB, Agar GE. The effect of slime coatings of the serpentine minerals, chrysotile and lizardite, on pentlandite flotation. Int. J. Miner. Process., 1980, 7(1): 33.

[7]	Feng B, Peng JX, Zhang WP, Luo GD, Wang HH. Removal behavior of slime from pentlandite surfaces and its effect on flotation. Miner. Eng., 2018, 125, 150.

[8]	Bobicki ER, Liu QX, Xu ZH. Effect of microwave pre-treatment on ultramafic nickel ore slurry rheology. Miner. Eng., 2014, 61, 97.

[9]	Cao J, Tian XD, Luo YC, Hu XQ, Xu PF. The effect of graphene oxide on the slime coatings of serpentine in the flotation of pentlandite. Colloids Surf. A, 2017, 522, 621.

[10]	Lu YP, Long T, Feng QM, Ou LM, Zhang GF. Flotation and its mechanism of fine serpentine. Chin. J. Nonferrous Met., 2009, 19(8): 1493.

[11]	Li C, Sun CY, Wang YL, Fu YF, Xu PY, Yin WZ. Research on new beneficiation process of low-grade magnesite using vertical roller mill. Int. J. Miner. Metall. Mater., 2020, 27(4): 432.

[12]	Tartaj P, Cerpa A, García-González MT, Serna CJ. Surface instability of serpentine in aqueous suspensions. J. Colloid Interface Sci., 2000, 231(1): 176.

[13]	M. Irannajad, O. Salmani Nuri, and A. Mehdilo, Surface dissolution-assisted mineral flotation: A review, J. Environ. Chem. Eng., 7(2019), No. 3, art. No. 103050.

[14]	Zhu YG, Zhang GF, Feng QM, Yan DC, Wang WQ. Effect of surface dissolution on flotation separation of fine ilmenite from titanaugite. Trans. Nonferrous Met. Soc. China, 2011, 21(5): 1149.

[15]	X.K. Tang and Y.F. Chen, Using oxalic acid to eliminate the slime coatings of serpentine in pyrite flotation, Miner. Eng., 149(2020), art. No. 106228.

[16]	Alvarez-Silva M. Surface Chemistry Study on Pentlandite-Serpentine System, 2010, Montreal, McGill University

[17]	Cao Z, Zhang YH, Sun CY, Cao YD. Activation mechanism of serpentine by Cu(II) and Ni(II) ions in copper-nickel sulfide ore flotation. Chin. J. Nonferrous Met., 2014, 24(2): 506.

[18]	Patra P, Bhambani T, Nagaraj DR, Somasundaran P. Dissolution of serpentine fibers under acidic flotation conditions reduces inter-fiber friction and alleviates impact of pulp rheological behavior on Ni ore beneficiation. Colloids Surf. A, 2014, 459, 11.

[19]	Tutolo BM, Luhmann AJ, Tosca NJ, Seyfried WE. Serpentinization as a reactive transport process: The brucite silicification reaction. Earth Planet. Sci. Lett., 2018, 484, 385.

[20]	Boschi C, Dini A, Baneschi I, Bedini F, Perchiazzi N, Cavallo A. Brucite-driven CO₂ uptake in serpentinized dunites (Ligurian Ophiolites, Montecastelli, Tuscany). Lithos, 2017, 289, 264.

[21]	Ding H, He SN, Cui J, Lin H. Flotation separation of brucite and serpentine using FL as collector. Multipurpose Util. Miner. Resour., 1993, 2, 5.

[22]	Li D, Jing J, Liang X. Study on comprehensive utilization of hydrazine serpentine in Ji’an County, Jilin Province. Build. Mater. Geol., 1987, 2, 30.

[23]	Zhu DS. Research on the Flotation for Desilication of High-Silicon Brucite Ore in Kuandian of Liaoning, 2011, Shenyang, Northeastern University

[24]	Fu YF, Zhu ZL, Yao J, Han HL, Yin WZ, Yang B. Improved depression of talc in chalcopyrite flotation using a novel depressant combination of calcium ions and sodium lignosulfonate. Colloids Surf. A, 2018, 558, 88.

[25]	Gao YS, Gao ZY, Sun W, Yin ZG, Wang JJ, Hu YH. Adsorption of a novel reagent scheme on scheelite and calcite causing an effective flotation separation. J. Colloid Interface Sci., 2018, 512, 39.

[26]	B. Yang, Z.L. Zhu, H.R. Sun, W.Z. Yin, J. Hong, S.H. Cao, Y. Tang, C. Zhao, and J. Yao, Improving flotation separation of apatite from dolomite using PAMS as a novel eco-friendly depressant, Miner. Eng., 156(2020), art. No. 106492.

[27]	Fu YF, Yin WZ, Yang B, Li C, Zhu ZL, Li D. Effect of sodium alginate on reverse flotation of hematite and its mechanism. Int. J. Miner. Metall. Mater., 2018, 25(10): 1113.

[28]	Jiang W, Gao ZY, Khoso SA, Jia DG, Sun W, Pu W, Hu YH. Selective adsorption of benzhydroxamic acid on fluorite rendering selective separation of fluorite/calcite. Appl. Surf. Sci., 2018, 435, 752.

[29]	J. Schott, O.S. Pokrovsky, and E.H. Oelkers, The link between mineral dissolution/precipitation kinetics and solution chemistry, [in] E.H. Oelkers and J. Schott, eds., Thermodynamics and Kinetics of Water-Rock Interaction, Berlin, Boston, 2009, p. 207.

[30]	Liu WY, Moran CJ, Vink S. A review of the effect of water quality on flotation. Miner. Eng., 2013, 53, 91.

[31]	Rao F, Lázaro I, Ibarra LA. Solution chemistry of sulphide mineral flotation in recycled water and sea water: A review. Miner. Process. Extr. Metall., 2017, 126(3): 139.

[32]	Araújo ACA, Lima RMF. Influence of cations Ca²⁺, Mg²⁺ and Zn²⁺ on the flotation and surface charge of smithsonite and dolomite with sodium oleate and sodium silicate. Int. J. Miner. Process., 2017, 167, 35.

[33]	Yin WZ, Tang Y. Interactive effect of minerals on complex ore flotation: A brief review. Int. J. Miner. Metall. Mater., 2020, 27(5): 571.

[34]	Guan QJ, Hu YH, Tang HH, Sun W, Gao ZY. Preparation of α-CaSO₄·½H₂O with tunable morphology from flue gas desulphurization gypsum using malic acid as modifier: A theoretical and experimental study. J. Colloid Interface Sci., 2018, 530, 292.

[35]	Farrokhpay S. The importance of rheology in mineral flotation: A review. Miner. Eng., 2012, 36–38, 272.

[36]	Li C, Runge K, Shi FN, Farrokhpay S. Effect of flotation froth properties on froth rheology. Powder Technol., 2016, 294, 55.

[37]	Z.L. Zhu, D.H. Wang, B. Yang, W.Z. Yin, M.S. Ardakani, J. Yao, and J.W. Drelich, Effect of nano-sized roughness on the flotation of magnesite particles and particle-bubble interactions, Miner. Eng., 151(2020), art. No. 106340.

[38]	Wang L, Peng Y, Runge K, Bradshaw D. A review of entrainment: Mechanisms, contributing factors and modelling in flotation. Miner. Eng., 2015, 70, 77.

[39]	J.J. Wang, W.H. Li, Z.H. Zhou, Z.Y. Gao, Y.H. Hu, and W. Sun, 1-Hydroxyethylidene-1,1-diphosphonic acid used as pH-dependent switch to depress and activate fluorite flotation I: Depressing behavior and mechanism, Chem. Eng. Sci., 214(2020), art. No. 115369.

[40]	Li HL, Xu WN, Jia FF, Li JB, Song SX, Nahmad Y. Correlation between surface charge and hydration on mineral surfaces in aqueous solutions: A critical review. Int. J. Miner. Metall. Mater., 2020, 27(7): 857.

[41]	Yang SY, Xie BH, Lu YP, Li C. Role of magnesium-bearing silicates in the flotation of pyrite in the presence of serpentine slimes. Powder Technol., 2018, 332, 1.

[42]	Guven O, Celik MS, Drelich JW. Flotation of methylated roughened glass particles and analysis of particle-bubble energy barrier. Miner. Eng., 2015, 79, 125.

[43]	Lu JW, Yuan ZT, Liu JT, Li LX, Zhu S. Effects of magnetite on magnetic coating behavior in pentlandite and serpentine system. Miner. Eng., 2015, 72, 115.

[44]	Li D, Yin WZ, Liu Q, Cao SH, Sun QY, Zhao C, Yao J. Interactions between fine and coarse hematite particles in aqueous suspension and their implications for flotation. Miner. Eng., 2017, 114, 74.

[45]	Ansarinasab J, Jamialahmadi M. Investigating the effect of interfacial tension and contact angle on capillary pressure curve, using free energy Lattice Boltzmann Method. J. Nat. Gas Sci. Eng., 2016, 35, 1146.

[46]	Farahat M, Hirajima T, Sasaki K, Doi K. Adhesion of Escherichia coli onto quartz, hematite and corundum: Extended DLVO theory and flotation behavior. Colloids Surf. B, 2009, 74(1): 140.

[47]	Xia YC, Rong GQ, Xing YW, Gui XH. Synergistic adsorption of polar and nonpolar reagents on oxygen-containing graphite surfaces: Implications for low-rank coal flotation. J. Colloid Interface Sci., 2019, 557, 276.

[48]	Alvarez-Silva M, Mirnezami M, Uribe-Salas A, Finch JA. Point of zero charge, isoelectric point and aggregation of phyllosilicate minerals. Can. Metall. Q., 2010, 49(4): 405.