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62 |
Optimization of microwave carbothermal reduction for processing of banded hematite jasper ore Rayapudi V, Agrawal S, Dhawan N Minerals Engineering, 138, 204, 2019 |
63 |
Dynamic capture behavior of ferromagnetic particles based on fully coupled multiphysics model of particle-fluid interactions Wang FW, Dai HX, Lv YC, Zhang L Minerals Engineering, 138, 238, 2019 |
64 |
Effect of carboxymethyl starch on fine-grained hematite recovery by high-intensity magnetic separation: Experimental investigation and theoretical analysis Li WB, Zhou LB, Han YX, Zhu YM, Li YJ Powder Technology, 343, 270, 2019 |
65 |
High gradient magnetic separation with involved Basset history force: Configuration with single axial wire Krafcik A, Babinec P, Babincova M, Frollo I Powder Technology, 347, 50, 2019 |
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A novel process to upgrade the copper slag by direct reduction-magnetic separation with the addition of Na2CO3 and CaO Li SW, Pan J, Zhu DQ, Guo ZQ, Xu JW, Chou JL Powder Technology, 347, 159, 2019 |
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Thermally assisted magnetic separation and characterization studies of a low-grade hematite ore Dash N, Rath SS, Angadi SI Powder Technology, 346, 70, 2019 |
68 |
The role of sodium oleate (NaOL) in the magnetic separation of pentlandite from serpentine using magnetic coating Lu JW, Yuan ZT, Li MM, Zhao X, Tong ZY, Li LX, Qi SL Powder Technology, 345, 492, 2019 |
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Innovative utilization of refractory iron ore via suspension magnetization roasting: A pilot-scale study Zhang XL, Han YX, Sun YS, Li YJ Powder Technology, 352, 16, 2019 |
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Modeling of particle capture in high gradient magnetic separation: A review Zheng XY, Xue ZX, Wang YH, Zhu GL, Lu DF, Li XD Powder Technology, 352, 159, 2019 |