矿物胶体与界面化学、硫化矿和磷矿浮选药剂与理论、微细粒矿物浮选理论与工艺、矿物材料制备与应用

[1] 国家自然科学基金面上项目，No. 52074196，基于非均质棱界面靶向调控的微细粒辉钼矿浮选研究，2021.01-2025.12，主持

[2] 国家自然科学基金中德合作项目，No. GZ1693, 微细粒磷灰石疏水聚团和聚团浮选研究，2022.01-2024.12，主持

[3] 国家自然科学基金青年基金，No.51704212，基于氧化方式选择性抑制黄铜矿的铜钼浮选分离基础研究，2018.01-2021.12，主持

[4] 企业委托项目，尾矿资源综合利用-氢氧化镁粉体改性制备高性能阻燃剂的研究，2017.04-2020.04，主持

[5] 金沙集团1862cc成色科学研究基金，K201733，新型高效黄铜矿抑制剂开发及其在铜钼分离中应用，2017.1-2018.12，主持

[6] 湖北省自然科学基金面上项目，No.2017CFB280，2017-2019，主持

[7] 国家自然科学基金青年项目，B081101，风化壳淋积型稀土矿羧酸盐浸出过程强化研究，参与

[8] 湖北省重点科研计划项目，No.2022BCA062，熔剂性鲕状赤铁矿低碳选冶关键技术研究与应用，2022-2025，参入

[1]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).

[2]B. Yang*, H. Yan, M. Zeng, H. Zhu, 2021, Tiopronin as a novel copper depressant for the selective flotation separation of chalcopyrite and molybdenite, Separation and Purification Technology, 266: 118576 (IF: 9.136).

[3]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).

[4]M. Zeng, B. Yang*, Z. Guan, L. Zeng, H. Luo, 2021, The selective adsorption of xanthan gum on dolomite and its implication in the flotation separation of dolomite from apatite, Applied Surface Science, 551: 149301 (IF:7.392).

[5] 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: 7.392).

[6]J. Wu, B. Yang*, S. Song, M. Quintana, F. Jia, X. Tian*, 2022, The efficient recovery of molybdenite fines using a novel collector: Flotation performances, adsorption mechanism and DFT calculation, Minerals Engineering,188:107848 (IF 5.479).

[7]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).

[8] B. Yang*, M. Zeng, H. Zhu, P. Huang, Z. Li, S. Song, 2021, Selective depression of molybdenite using a novel eco-friendly depressant in Cu-Mo sulfides flotation system, Colloids and Surfaces A：Physicochemical and Engineering Aspects, 622:126683 (IF:5.518).

[9] Y. Hu,Z. Zhao, L. Lu, H. Zhu, W. Xiong, Y. Zhu, S. Luo, X. Zhang, B.Yang*, 2021, Investigation on a novel galena depressant in the flotation separation from molybdenite, Minerals,4:410 (IF:2.818).

[10] H. Yan, B. Yang*, H. Zhu, P. Huang, Y.Hu, 2021, Selective flotation of Cu-Mo sulfides using dithiothreitol as an environmental-friendly depressant, Minerals Engineering,168:106929 (IF:5.479).

[11] M. Zeng, B. Yang*, H. Yan, H. Qu, Y. Hu, 2020, Efficient recovery of Ag(I) from aqueous solution using MoS₂nanosheets: adsorption study and DFT calculation, Chemical Physics Letters, 757:137865 (IF:2.719).

[12] B. Yang*, H. Yan, M. Zeng, P. Huang, F. Jia, A. Teng, 2020, A novel copper depressant for selective flotation of chalcopyrite and molybdenite, Minerals Engineering,151: 106309 (IF: 5.479).

[13] H. Yan, B. Yang*, M. Zeng, P. Huang, A. Teng, 2020, Selective flotation of Cu-Mo sulfides using xanthan gum as a novel depressant, Minerals Engineering,156:106486 (IF: 5.479).

[14] Q. Zhang, H. Zhu, B. Yang*,F. Jia, H. Yan, M. Zeng, H. Qu, 2019, Effect of Pb²⁺ on the flotation of molybdenite in the presence of sulfide ion, Results in Physics, 14:102361(IF:4.565).

[15] B. Yang*, D. Wang, T. Wang, H. Zhang, F. Jia, S. Song, 2019, Effect of Cu²⁺ and Fe³⁺on the depression of molybdenite in flotation, Minerals Engineering,130:101-109 (IF: 5.479).

[16] J. Wu, E. Mario, B. Yang*, C. Liu, F. Jia, S. Song, 2018, Efficient removal of Hg²⁺ in aqueous solution with fishbone charcoal as adsorbent, Environmental Science and Pollution Research, 25(8): 7709-7718 (IF:5.190).

[17] B. Yang*, P. Huang, S. Song, H. Luo, Y. Zhang, 2018, Hydrophobic agglomeration of apatite fines induced by sodium oleate in aqueous solutions, Results in Physics, 9:970-977 (IF:4.565).

[18]W. Xu, B. Yang*, F. Jia, T. Chen, L. Lang, S. Song, 2018, Removal of As(V) from aqueous solution by using cement-porous hematite composite granules as adsorbent, Results in Physics, 11:23-29 (IF:4. 565).

[19]J. Ni, B. Yang*, F. Jia, Y. She, S. Song, M. Quintana, 2018, Theoretical investigation of the sensing mechanism of the pure graphene and AL, B, N, P doped mono-vacancy graphene-based methane, Chemical Physics Letters, 710:221-225 (IF:2.719).

[20] Y. Zhang, H. Chen, B. Yang*, S. Fu, J. Yu, Z. Wang, 2018, Prediction of phosphate concentrate grade based on artificial neural network modeling, Results in Physics, 11:625-628 (IF: 4. 565).

[21]严海，杨丙桥^*，曾梦媛，冯金婵，朱环宇，基于过硫酸铵氧化的铜钼分离研究[J].中国有色金属学报，2021，已收录.

[22]黄鹏亮，杨丙桥^*，严海，曾梦媛，氧化预处理对铜钼分离的影响[J].矿冶工程, 2021,已收录.

[23]关智文，杨丙桥^*，胡杨甲，一种新型辉钼矿抑制剂及其在铜钼浮选分离中的机理研究[J].有色金属（选矿部分），2021，已收录.

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[25]杨丙桥^*，黄鹏亮，张汉泉，贾菲菲，微细粒辉钼矿疏水聚团及聚团浮选研究[J].金属矿山，2018(10):86-91.

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[1] 2022年，金沙集团1862cc成色青年拔尖人才

[2] 2021年，金沙集团1862cc成色科研工作先进个人

[3] 2021年，金沙集团1862cc成色优秀导师

[4] 2020年，金沙集团1862cc成色优秀班主任

[5] 2016年，墨西哥科技部研究水平1级

l学生工作：