浮選藥劑、礦物膠體與界面化學、礦物浮選理論與工藝

[1] 國家自然科學基金面上項目，No.52374272，矽鈣質膠磷礦短流程分選浮選藥劑分子靶向設計基礎研究，2024.01-2027.12，50萬，主持

[2] 國家自然科學基金面上項目，No.52074196，基于非均質棱界面靶向調控的微細粒輝钼礦浮選研究，2021.01-2024.12，58萬，主持

[3] 湖北省自然科學基金傑出青年基金，No.2023AFA047,2024.01-2026.12，30萬，主持

[4] 自然資源部戰略性礦産綜合利用工程技術創新中心開放基金項目，No. CCUM-KY-01,2023.10-2024.10，10萬，主持

[5] 國家自然科學基金中德合作項目（德國優青），No.GZ1693，微細粒磷灰石疏水聚團和聚團浮選研究，2022.01-2024.12，44.9萬，主持

[6] 國家自然科學基金青年基金，No.51704212，基于氧化方式選擇性抑制黃銅礦的銅钼浮選分離基礎研究，2018.01-2021.12，25萬，主持

[7] 企業委托項目，“一種白雲石的抑制劑及其使用方法”發明專利技術轉讓，2022年，10萬，主持

[8] 湖北省自然科學基金面上項目，No.2017CFB280，2017-2019，5萬，主持

[9] 77779193永利官网科學研究基金，K201733，新型高效黃銅礦抑制劑開發及其在銅钼分離中應用，2017.1-2018.12，5萬，主持

[10] 企業委托項目，尾礦資源綜合利用-氫氧化鎂粉體改性制備高性能阻燃劑的研究，2017.04-2020.04，20萬，主持

[11] 湖北省重點科研計劃項目，No.2022BCA062，熔劑性鲕狀赤鐵礦低碳選冶關鍵技術研究與應用，2022-2025，100萬，主要參入

[1] R. Ge, B. Yang*, Bing Deng, Hui Shao, Yimei Xiao, Rudolph Martin, H. Luo, H. Zhang, 2024, The interaction mechanism of a novel polymer depressant with apatite and dolomite surface and its implication on flotation: Experimental tests and DFT calculation, Applied Surface Science, 643:158675 (IF 6.7)

[2] R. Ge, B. Yang*, R. Martin, H. Luo, D. He, M. Corona Arroyo, 2023, The application of poly (sodium 4-styrene sulfonate) as an efficient dolomite depressant in the direct flotation of apatite from dolomite, Powder Technology, 425:118583 (IF 5.2)

[3] J. Wu, J. Feng, B. Yang, R. Martin, S. Song, M. Quintana, F. Jia, X. Tian, 2023, The anisotropic adsorption of potassium cetyl phosphate on molybdenite surface and its implication for improving the flotation of molybdenite fines, Journal of Molecular Liquids, 378: 121616 (IF 6.1)

[4] H. Zhu, B. Yang*, J. Feng, 2021, Evaluation of 1-hydroxyethylidene-1,1-diphosphonic acid as an efficient and low-toxic sphalerite depressant in the selective flotation of galena from sphalerite, Journal of Cleaner Production, 329: 129612 (IF 11.072)

[5] J. Wu, B. Yang, R. Martin, S. Song, M. Quintana, F. Jia, H. Luo, F. Zhou, 2024, Anisotropic adsorption of xanthate species on molybdenite faces and edges and its implication on the flotation of molybdenite fines, Minerals Engineering, 207:108571 (IF:4.80)

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[7] B. Yang*, H. Zhu, J. Feng, L. Zeng, H. Luo, 2021, An environmental-friendly sphalerite depressant (2-HydroxyphosphonoaceticAcid) for the selective flotation separation of sphalerite from galena, Journal of Molecular Liquids, 343: 117614 (IF 6.633)

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[9] J. Feng, B. Yang*, H. Zhu, H. Zhang, M. Zeng, 2021, The utilization of 2-phosphonobutane-1,2,4-tricarboxylic acid (PBTCA) as a novel sphalerite depressant in the selective flotation of galena from sphalerite, Applied Surface Science, 569:150950 (IF: 6.7).

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[11] Y. Xiao, J. Feng, B. Yang^*, H. Luo, F. Zhou, 2024, The combination of calcium hypochlorite and fulvic acid as an efficient arsenopyrite depressant in Cu-As separation, Minerals Engineering, 206:10784978 (IF 5.479)

[12] B. Yang*, P. Huang, Q An, 2022, An efficient chalcopyrite depressant for Cu-Mo separation and its interaction mechanism: Adsorption configuration and DFT calculations, Journal of Molecular Liquids, 345: 118171 (IF 6.633).

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