The depression of pyrite in selective flotation by different reagent systems–A Literature review Y Mu, Y Peng, RA Lauten Minerals Engineering 96, 143-156, 2016 | 237 | 2016 |
Electrochemistry aspects of pyrite in the presence of potassium amyl xanthate and a lignosulfonate-based biopolymer depressant Y Mu, Y Peng, RA Lauten Electrochimica Acta 174, 133-142, 2015 | 67 | 2015 |
Separation of bastnäsite from fluorite using ethylenediamine tetraacetic acid as depressant Z Cao, Y Cao, Q Qu, J Zhang, Y Mu Minerals Engineering 134, 134-141, 2019 | 61 | 2019 |
Surface properties of fractured and polished pyrite in relation to flotation Y Mu, L Li, Y Peng Minerals Engineering 101, 10-19, 2017 | 56 | 2017 |
The galvanic interaction between chalcopyrite and pyrite in the presence of lignosulfonate-based biopolymers and its effects on flotation performance Y Mu, Y Peng, RA Lauten Minerals Engineering 122, 91-98, 2018 | 55 | 2018 |
The depression of copper-activated pyrite in flotation by biopolymers with different compositions Y Mu, Y Peng, RA Lauten Minerals Engineering 96, 113-122, 2016 | 51 | 2016 |
The mechanism of pyrite depression at acidic pH by lignosulfonate-based biopolymers with different molecular compositions Y Mu, Y Peng, RA Lauten Minerals Engineering 92, 37-46, 2016 | 51 | 2016 |
The role of sodium metabisulphite in depressing pyrite in chalcopyrite flotation using saline water Y Mu, Y Peng Minerals Engineering 142, 105921, 2019 | 41 | 2019 |
The effect of saline water on copper activation of pyrite in chalcopyrite flotation Y Mu, Y Peng Minerals Engineering 131, 336-341, 2019 | 40 | 2019 |
The interaction of grinding media and collector in pyrite flotation at alkaline pH Y Mu, Y Cheng, Y Peng Minerals Engineering 152, 106344, 2020 | 31 | 2020 |
The interaction between grinding media and collector in pyrite flotation at neutral and slightly acidic pH Y Mu, Y Cheng, Y Peng Minerals Engineering 145, 106063, 2020 | 24 | 2020 |
Comparing lead and copper activation on pyrite with different degrees of surface oxidation X Yang, Y Mu, Y Peng Minerals Engineering 168, 106926, 2021 | 12 | 2021 |
Particle size distribution of metallic iron during coal-based reduction of an oolitic iron ore Y Han, Y Sun, P Gao, Y Li, Y Mu Mining, Metallurgy & Exploration 31, 169-174, 2014 | 12 | 2014 |
Selectively depress copper-activated pyrite in copper flotation at slightly alkaline pH Y Mu, Y Peng Mining, Metallurgy & Exploration 38, 751-762, 2021 | 10 | 2021 |
The flotation of pyrite and chalcopyrite in the presence of biopolymers Y Mu, Y Peng, R Lauten Gecamin Publications 1, 132-142, 2014 | 9 | 2014 |
Particle size measurement of metallic iron in reduced materials based on optical image analysis Y Sun, Y Han, P Gao, Y Mu Chemical Engineering & Technology 37 (12), 2030-2036, 2014 | 7 | 2014 |
Maximise pyrite depression in copper ore flotation using high salinity water Y Mu, Y Peng Minerals Engineering 196, 108060, 2023 | 5 | 2023 |
Pilot beneficiation about deoxidized samples of Bayan Obo oxidized iron ore P Gao, YX Han, YS Sun, YF Mu Advanced Materials Research 454, 221-226, 2012 | 4 | 2012 |
The modification of bubble characteristics and chalcopyrite surface hydrophobicity in water containing NaCl M Hwang, Y Mu, L Cao, Y Peng Journal of Molecular Liquids 385, 122391, 2023 | 3 | 2023 |
The roles of lead ions in restoring the floatability of pyrite depressed by free cyanide X Yang, Y Mu, Y Peng Minerals Engineering 175, 107289, 2022 | 3 | 2022 |