汤永健
职称:特聘副研究员,硕士生导师
地址:8858cc永利皇宫登录实验16楼215室
电话:18818209440
电子邮件:tangyongjian@ecust.edu.cn
教育背景:
2008.9-2012.6 南京工业大学8858cc永利皇宫登录本科
2012.9-2017.6 8858cc永利皇宫登录硕博连读
工作经历:
2017.05-2019.05 8858cc永利皇宫登录师资博士后
2019.06-至今8858cc永利皇宫登录特聘副研究员
学术兼职:
中国海水淡化与水再利用学会青年专家委员会委员;Journal of Membrane Science, Separation and Purification Technology, Environmental Science & Technology, ACS Applied Materials & Interfaces等期刊审稿人。
科研项目:
1.国家自然科学基金青年基金,“含氟聚酰胺纳滤膜微观结构调控及分子模拟的研究”,2019-2021,25万,主持
2.教育部基本科研业务费,“3D立体微结构纳滤膜构建、调控及性能”,2018-2019,16万,主持
3.8858cc永利皇宫登录科研启动基金,“高渗透选择性纳滤膜设计及性能调控”,2019-2022,50万,主持
4.宝山钢铁股份有限公司,“含油废水高效回用技术开发研究”,2020-2022,21.6万,主持
5.宝武水务科技有限公司,“硅钢废水零排放技术研究”,2022,29.2万,主持
6.企业委托项目,“分子筛在液压油除水过程中的应用与性能评估”,2020,22万,主持
7.企业委托项目,“低成本锂电池回收工艺研发与膜元件设计软件升级技术”,2022-2024,80万,主持
8.企业委托项目,“药物合成过程溶剂回收与纯化、精制技术(研发级别)”,2021-2022,30万,主持
研究方向:
1.分离膜新型制备方法及其应用
2.特种分离膜结构调控与规模化制备
3.废水/废溶剂/退役锂电池资源化利用
主要学术成果:
迄今为止发表SCI论文30余篇,其中第一作者/通讯作者23篇,包括国际一流期刊Journal of Membrane Science(12篇),Industrial and Engineering Chemistry Research(4篇), ACS Applied Materials and Interfaces,Separation and Purification Technology等。获授权中国发明专利2项,参编《膜技术手册》(第二版)。
[1] Y.-J. Tang, Z.-L. Xu*, S.-M. Xue, Y.-M. Wei, H. Yang, A chlorine-tolerant nanofiltration membrane prepared by the mixed diamine monomers of PIP and BHTTM, Journal of Membrane Science, 498 (2016) 374-384.
[2] Y.-J. Tang, L.-J. Wang, Z.-L. Xu*, Y.-M. Wei, H. Yang, Novel high-flux thin film composite nanofiltration membranes fabricated by the NaClO pre-oxidation of the mixed diamine monomers of PIP and BHTTM in the aqueous phase solution, Journal of Membrane Science, 502 (2016) 106-115.
[3] Y.-J. Tang, Z.-L. Xu*, S.-M. Xue, Y.-M. Wei, H. Yang, Tailoring the polyester/polyamide backbone stiffness for the fabrication of high performance nanofiltration membrane, Journal of Membrane Science, 541 (2017) 483-491.
[4] Y.-J. Tang, Z.-L. Xu*, S.-M. Xue, Y.-M. Wei, H. Yang, Improving the chlorine-tolerant ability of polypiperazine-amide nanofiltration membrane by adding NH2-PEG-NH2 in the aqueous phase, Journal of Membrane Science, 538 (2017) 9-17.
[5] Y.-J. Tang, B.-J. Shen, B.-Q. Huang, Z.-M. Zhan, Z.-L. Xu*, High permselectivity thin-film composite nanofiltration membranes with 3D microstructure fabricated by incorporation of beta cyclodextrin, Separation and Purification Technology, 227 (2019) 115718.
[6] Z.-M. Zhan, Z.-L. Xu, K.-K. Zhu, Y.-J. Tang*, How to understand the effects of heat curing conditions on the morphology and performance of polypiperazine-amide NF membrane, Journal of Membrane Science, (2019) 117640.
[7] B.-Q. Huang, Y.-J. Tang*, Z.-X. Zeng, Z.-L. Xu*, Microwave heating assistant preparation of high permselectivity polypiperazine-amide nanofiltration membrane during the interfacial polymerization process with low monomer concentration, Journal of Membrane Science, 596 (2020) 117718.
[8] B.-Q. Huang, Y.-J. Tang*, Z.-X. Zeng, S.-M. Xue, C.-H. Ji, Z.-L. Xu*, High-Performance Zwitterionic Nanofiltration Membranes Fabricated via Microwave-Assisted Grafting of Betaine, ACS Applied Materials & Interfaces, 12 (2020) 35523-35531.
[9] Z.-M. Zhan, Z.-L. Xu, K.-K. Zhu, S.-M. Xue, C.-H. Ji, B.-Q. Huang, C.Y. Tang, Y.-J. Tang*, Superior nanofiltration membranes with gradient cross-linked selective layer fabricated via controlled hydrolysis, Journal of Membrane Science, 604 (2020) 118067.
[10] L.-Q. Li, Z.-M. Zhan, B.-Q. Huang, S.-M. Xue, C.-H. Ji, R.-Z. Wang, Y.-J. Tang*, Z.-L. Xu*, RO membrane fabricated via a facile modified heat-treating strategy for high-flux desalination, Journal of Membrane Science, 614 (2020) 118498.
[11] Z.-M. Zhan, X. Zhang, Y.-X. Fang, Y.-J. Tang*, K.-K. Zhu, X.-H. Ma, Z.-L. Xu*, Polyamide Nanofiltration Membranes with Enhanced Desalination and Antifouling Performance Enabled by Surface Grafting Polyquaternium-7, Industrial & Engineering Chemistry Research, 60 (2021) 14297-14306.
[12] Z.-M. Zhan, Y.-J. Tang*, K.-K. Zhu, S.-M. Xue, C.-H. Ji, C.Y. Tang, Z.-L. Xu*, Coupling heat curing and surface modification for the fabrication of high permselectivity polyamide nanofiltration membranes, Journal of Membrane Science, 623 (2021) 119073.
[13] B.-Q. Huang, Y.-J. Tang*, A.-R. Gao, Z.-X. Zeng, S.-M. Xue, C.-H. Ji, C.Y. Tang, Z.-L. Xu*, Dually charged polyamide nanofiltration membranes fabricated by microwave-assisted grafting for heavy metals removal, Journal of Membrane Science, 640 (2021) 119834.
[14] B.-Q. Huang, Y.-J. Tang*, Z.-X. Zeng, S.-M. Xue, S.-Q. Li, Y.-R. Wang, E.-C. Li, C.Y. Tang, Z.-L. Xu*, Enhancing nanofiltration performance for antibiotics/NaCl separation via water activation before microwave heating, Journal of Membrane Science, 629 (2021) 119285.
[15] Li, L.-Q, Liu, X.-H, Tang, Y.-J*, Xu, Z.-L*, How Does Alkali Etching Work on the Polyamide Membrane to Obtain an m-Phenylenediamine-Based NF Membrane?Industrial & Engineering Chemistry Research, 61 (2022)5536 - 5546.
[16] Zhu, Q.-Y, Wu, L.-K, Li, L.-Q, Xu, Z.-L, Tang, Y.-J*,Novel Insight on the Effect of the Monomer Concentration on the Polypiperazine-Amide Nanofiltration Membrane, Industrial & Engineering Chemistry Research, 61 (2022)5843 - 5852.
[17]Li, L.-Q, Tang, Y.-J*, Xu, Z.-L*.Can the NF membrane directly obtained by the interfacial polymerization of MPD and TMC? Journal of Membrane Science, 656 (2022) 120618.
[18]Liu-Kun Wu, Qiu-Yu Zhu, Lan-Qian Li, Zhen-Liang Xu, Shuang-Mei Xue, Chen-Hao Ji, Chuyang Y. Tang, Liwei Zhuang, Yong-Jian Tang*, Exploration of Permeation Resistance Change of the Polyamide Nanofiltration Membrane during Heat Curing by Using Organic Molecules as Functional Fillers, Industrial & Engineering Chemistry Research, 2022https://doi.org/10.1021/acs.iecr.2c02553.