Hemimorphite exhibits poor floatability during sulfidization flotation. Cu2+ and Pb2+ addition enhances the reactivity of the hemimorphite surface and subsequently improves its flotation behavior. In this study, the mechanisms of Cu2+ + Pb2+ adsorption onto a hemimorphite surface were investigated. We examined the interaction mechanism of xanthate with the hemimorphite surface and observed the changes in the mineral surface hydrophobicity after the synergistic activation with Cu2+ + Pb2+. Microflotation tests indicated that individual activation with Cu2+ or Pb2+ increased the flotation recovery of hemimorphite, with Pb2+ showing greater effectiveness than Cu2+. Meanwhile, synergistic activation with Cu2+ + Pb2+ considerably boosted the flotation recovery of hemimorphite. Cu2+ and Pb2+ were both adsorbed onto the hemimorphite surface, forming an adsorption layer containing Cu or Pb. Following the synergistic activation with Cu2+ + Pb2+, the activated layer on the hemimorphite surface consisted of Cu and Pb and a larger amount of the active product compared with the surface activated by Cu2+ or Pb2+ alone. In addition, xanthate adsorption on the hemimorphite surface increased noticeably after synergistic activation with Cu2+ + Pb2+, suggesting a vigorous reaction between xanthate and the activated minerals. Therefore, synergistic activation with Cu2+ + Pb2+ effectively increased the content of active products on the hemimorphite surface, thereby enhancing mineral surface reactivity, promoting collector adsorption, and improving surface hydrophobicity.
| [1] |
AbkhoshkE, JorjaniE, Al-HarahshehMS, RashchiF, NaazeriM. Review of the hydrometallurgical processing of non-sulfide zinc ores. Hydrometallurgy, 2014, 149: 153
|
| [2] |
Y.H. Yi, P.X. Li, G. Zhang, Q.C. Feng, and G. Han, Stepwise activation of hemimorphite surfaces with lead ions and its contribution to sulfidization flotation, Sep. Purif. Technol., 299(2022), art. No. 121679.
|
| [3] |
ZhangX, WangY, DengJS, et al.. Effect of ammonium sulfate on the formation of zinc sulfide species on hemimorphite surface and its role in sulfidation flotation. Int. J. Miner. Metall. Mater., 2023, 30(11): 2147
|
| [4] |
Q.B. Cao, H. Zou, D.W. Liu, S.M. Wen, and X.M. Chen, Flotation separation of smithsonite from calcite using an amino-acid collector, Sep. Purif. Technol., 281(2022), art. No. 119980.
|
| [5] |
Y.J. Luo, G.F. Zhang, C.B. Li, et al., Flotation separation of smithsonite from calcite using a new depressant fenugreek gum, Colloids Surf. A, 582(2019), art. No. 123794.
|
| [6] |
DengRD, HuY, KuJG, MaYQ, YangZG. Ion migration law in flotation pulp and its influence on the separation of smithsonite and quartz. Sep. Sci. Technol., 2018, 53(5): 833
|
| [7] |
EjtemaeiM, IrannajadM, GharabaghiM. Role of dissolved mineral species in selective flotation of smithsonite from quartz using oleate as collector. Int. J. Miner. Process., 2012, 114: 40
|
| [8] |
FengQC, YangWH, ChangMH, WenSM, LiuDW, HanG. Advances in depressants for flotation separation of Cu–Fe sulfide minerals at low alkalinity: A critical review. Int. J. Miner. Metall. Mater., 2024, 31(1): 1
|
| [9] |
YaoJ, BanXQ, XieY, YinWZ, WangYL, XueFJ. Research advancement of efficient flotation separation technologies for magnesium-containing minerals. Green Smart Min. Eng., 2024, 1(2): 140
|
| [10] |
H.P. Zhou, Z.Z. Yang, Y.B. Zhang, F.X. Xie, and X.P. Luo, Flotation separation of smithsonite from calcite by using flaxseed gum as depressant, Miner. Eng., 167(2021), art. No. 106904.
|
| [11] |
EjtemaeiM, GharabaghiM, IrannajadM. A review of zinc oxide mineral beneficiation using flotation method. Adv. Colloid Interface Sci., 2014, 206: 68
|
| [12] |
ShiQ, FengQM, ZhangGF, DengH. Electrokinetic properties of smithsonite and its floatability with anionic collector. Colloids Surf. A, 2012, 410: 178
|
| [13] |
W.P. Liu, Z.X. Wang, X.M. Wang, and J.D. Miller, Smithsonite flotation with lauryl phosphate, Miner. Eng., 147(2020), art. No. 106155.
|
| [14] |
W. Tan, G.Y. Liu, J.Q. Qin, and H.L. Fan, Hemimorphite flotation with 1-hydroxydodecylidene-1, 1-diphosphonic acid and its mechanism, Minerals, 8(2018), No. 2, art. No. 38.
|
| [15] |
FengQC, YangWH, WenSM, WangH, ZhaoWJ, HanG. Flotation of copper oxide minerals: A review. Int. J. Min. Sci. Technol., 2022, 32(6): 1351
|
| [16] |
ZuoQ, YangJ, ShiYF, WuDD. Activating hemimorphite using a sulfidation-flotation process with sodium sulfosalicylate as the complexing agent. J. Mater. Res. Technol., 2020, 9(5): 10110
|
| [17] |
WangL, HuGY, SunW, KhosoSA, LiuRQ, ZhangXF. Selective flotation of smithsonite from dolomite by using novel mixed collector system. Trans. Nonferrous Met. Soc. China, 2019, 29(5): 1082
|
| [18] |
Z.Y. Song, S.M. Wen, G. Han, and Q.C. Feng, Recent progress on chelating reagents in flotation of zinc oxide ores: A review, Minerals, 13(2023), No. 10, art. No. 1278.
|
| [19] |
Q.C. Feng, G. Zhang, Q. Zhang, and W.J. Zhao, Synergistic activation of sulfidized hemimorphite with copper–lead species for improving surface hydrophobicity and floatability, Sep. Purif Technol., 332(2024), art. No. 125854.
|
| [20] |
ChenYG, SunYS, HanYX. Efficient flotation separation of lead–zinc oxide ores using mineral sulfidation reconstruction technology: A review. Green Smart Min. Eng., 2024, 1(2): 175
|
| [21] |
J.P. Cai, D.W. Liu, P.L. Shen, et al., Effects of heating-sulfidation on the formation of zinc sulfide species on smithsonite surfaces and its response to flotation, Miner. Eng., 169(2021), art. No. 106956.
|
| [22] |
JiangSP, ZhangGF, ChangYQ, FengQM, ZhangBF. Effect of metal ions on sulfiding flotation of smithsonite. Nonferrous Met. Miner. Process, 2016, 2: 23
|
| [23] |
ZhangGF, ZhangFY. Effect of metal ions on sulfiding flotation of hemimorphite. J. Cent. South Univ. Sci. Technol., 2017, 48(7): 1689
|
| [24] |
Y.Q. Huang, W.Z. Yin, R.D. Deng, D.Q. Xing, and F. Rao, Strengthening sulfidation flotation of hemimorphite via pretreatment with Pb2+, Minerals, 9(2019), No. 8, art. No. 463.
|
| [25] |
SehlothoN, SindaneZ, BrysonM, LindveltL. Flowsheet development for selective Cu–Pb–Zn recovery at Rosh Pinah concentrator. Miner. Eng., 2018, 122: 10
|
| [26] |
HanHS, HuYH, SunW, et al.. Fatty acid flotation versus BHA flotation of tungsten minerals and their performance in flotation practice. Int. J. Miner. Process., 2017, 159: 22
|
| [27] |
FanX, RowsonNA. The effect of Pb(NO3)2 on ilmenite flotation. Miner. Eng., 2000, 13(2): 205
|
| [28] |
WangZH, HanG, FengQC. Selective flotation of galena and sphalerite using N-(phosphonomethyl) iminodiacetic acid as an eco-friendly depressant. Green Smart Min. Eng., 2024, 1(1): 96
|
| [29] |
LiXK, ZhangY, HeHY, WuY, WuDY, GuanZH. Flotation separation of scheelite from calcite using luteolin as a novel depressant. Int. J. Miner. Metall. Mater., 2024, 31(3): 462
|
| [30] |
ShenZH, WenSM, WangH, et al.. Effect of dissolved components of malachite and calcite on surface properties and flotation behavior. Int. J. Miner. Metall. Mater., 2023, 30(7): 1297
|
| [31] |
LiuJ, LiuZG, TanJ, HuF. Flotation separation of pyrite from chalcopyrite by tetrazinan-thione collectors. J. Cent. South Univ., 2023, 30(8): 2587
|
| [32] |
Y.C. Zhang, W.J. Zhao, G. Han, and Q.C. Feng, A novel activation method for regulating surface characteristics and flotation performance of smithsonite: XPS, SEM-EDS, AFM, ToF-SIMS and FT-IR studies, Sep. Purif. Technol., 352(2025), art. No. 128276.
|
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