环境科学与工程学院-周明华导师介绍
周明华
教授
硕,博士生导师
男
环境科学与工程学院
环境科学与工程
水污染控制技术,环境催化与纳米材料,高级氧化技术,污水资源化、能源化
南开大学环境科学与工程学院教授、博士生导师,主要从事水处理技术与资源化研究,聚焦电化学高级氧化工艺、环境功能材料开发及污染控制工程应用。主持国家自然科学基金等多项科研项目,在Nature Communications、Environmental Science & Technology、Water Research等期刊发表论文百余篇,撰写英文专著1部,专著章节6个、教材3本。授权国家发明专利30项,同时担任多个国际期刊编委、国际电化学学会电化学过程工程和技术分会副主席 、中国环境科学学会水处理与回用专业委员会常务委员、中国化工学会工业水处理专业委员会委员、国际水协会水回用专家组管理委员会委员、中国环境科学学会水处理分会委员等多项学术职务,连续9年入选爱思唯尔中国高被引学者(环境科学)。
教育背景
1)教育经历
1998.09-2003.03,浙江大学,环境与资源学院环境工程系,硕博联读
1994.09-1998.07,浙江大学,化工学院环境工程系,本科
2)研究工作经历
2008.04- 今, 南开大学,环境科学与工程学院,教授、博士生导师;
其中:
2018.08-2018.09,法国东巴黎大学地球环境材料实验室,邀请教授;
2012.11-2013.02,德国不伦瑞克工业大学,环境与可持续化学研究所,高级访问学者; 2011.06-2011.07,芬兰拉彭兰塔科技大学,绿色化学实验室,访问学者;
2010.03-2010.04,法国马恩河谷大学,地球环境材料实验室,邀请教授;
2008.12-2009.03,芬兰库奥皮奥大学,环境应用化学实验室,居里学者;
2006.07-2008.01,悉尼大学,化学与生物分子工程学院,博士后研究员;
2005.12-2008.03,浙江大学,环资学院环境污染控制技术研究所,副教授;
2003.04-2005.11,浙江大学,环境与资源学院环境工程研究所,讲师;
学术与社会任职
Guest editor: Chemosphere (SCI)
Current Organic Chemistry (SCI)
Editorial Board: Separation and Purification Technology (SCI)
Chinese Chemical Letters (SCI) (高级编委:2021.7-2025.6)
Journal of Chemistry (SCI)
Catalyst (SCI)
Journal of Microbial & Biochemical Technology;
Editorial Advisory Board: Bioprocess & Biosystems Engineering (SCI)
编委: 工业水处理(2018.10-2022.10);
中国给水排水(2020.5-2022.5);
环境保护前沿;
国际电化学学会电化学过程工程和技术分会副主席 (2021-);
中国环境科学学会水处理与回用专业委员会常务委员(2023-);
中国化工学会工业水处理专业委员会委员(2022-2027)
国际水协会水回用专家组管理委员会委员;
国际水协会中国青年委员会委员;
中国农业生态环境保护协会常务理事;
中国有机电化学和工业联合会常务理事;
天津水利学会常务理事;
天津环境学会理事;
中国化学会高级会员;
中国电化学学会分委员会委员;
中国化学会青年工作者委员会委员;
中国生态学会咨询工作委员会委员;
教育部留学回国人员基金评审专家;
教育部博士点基金项目评审专家;
科技部重大研发计划项目评审专家
天津市人民政府学位委员会专业学位教育指导委员会成员
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科研项目
主持项目:
Ø 国家自然科学基金联合基金项目,煤化工高盐废水零排放和盐资源循环利用基础研究
Ø 国家重点研发计划国际合作项目,中西水处理电化学清洁技术联合实验室
Ø 国家重点研发计划国际合作项目,高效低耗光电催化处理难降解有机废水研究
Ø 国家自然科学基金面上项目,新型复合高级氧化技术构建及其高效低耗处理难降解有机物研究
Ø 国家自然科学基金面上项目,煤化工浓盐废水中有机物的电化学强化臭氧化去除效能与机制研究
Ø 国家自然科学基金面上项目,新型过滤式非均相电芬顿技术及其高效处理典型新兴有机污染物的研究
Ø国家自然科学基金重大研究计划培育项目,新型光合藻微生物燃料电池高效转化二氧化研究
Ø 国家自然科学基金面上项目,高效电化学多相催化体系的构建及其降解有机污染物机理研究
Ø 国家自然科学基金面上项目,阴阳两极耦合电化学转盘反应器处理难降解有机污染物研究
Ø 国家自然科学基金面上项目,非金属掺杂TiO2纳米管制备及其光电催化降解有机污染物研究
Ø 国家自然科学基金青年基金项目,湿式电催化氧化法处理高浓度难降解有机污染物的应用基础研究
Ø 国家自然科学基金国际合作与交流基金项目,同时处理废水和转化二氧化碳的先进电化学零能耗净化技术
Ø 国家自然科学基金委海外合作基金,用于腐蚀性生物膜检测及废水处理的微生物燃料电池新技术
Ø 国家自然科学基金, 电化学高级氧化技术的集成开发及应用于水中有机污染物的修复研究
Ø 天津自然科学重点基金,新型高效低耗电化学高级氧化技术的构建及耦合机制
Ø 天津市自然科学重点基金,新兴有机污染物复合污染的高效电化学协同控制技术研究
Ø 天津滨海新区中加合作项目,城市污水中新兴有机污染物的深度处理技术
Ø 国家水污染控制重大专项,海河南系独流减河流域水质改善和生态修复技术集成与示范
Ø 国家863项目,化工行业含氰废气净化技术与示范
Ø 国家863项目,高级氧化-吸附/生物-膜滤多级耦合给水深度处理技术
Ø 国家水专项,基于剩余浓水达标排放吸附-氧化处理技术
Ø 国家水专项, 松花江流域水生态一二级分区研究
Ø 教育部新世纪优秀人才基金,基于微生物燃料电池的污水能源化处理新技术研究
Ø 教育部博士点基金, 新型电化学转盘工艺处理难降解有机污染物的阴阳两极耦合机制研究
Ø 南开大学百人计划, 耦合微生物燃料电池的高效低耗环境电化学水处理技术
Ø 天津市自然科学基金, 太阳能光电催化降解有机污染物耦合制氢的研究
参加项目:
Ø 国家科技支撑计划,石油开采场地及周边地区污染土壤修复技术研究与示范
Ø 国家自然科学基金重点项目, 工业废水处理过程中的化工新技术与新方法研究
Ø 国家自然科学基金面上项目, 电化学转化法改善难降解有机废水可生化性的研究
Ø 国家自然科学基金面上项目, 原料气中有机硫在脉冲电晕作用下的硫回收机理
Ø 澳大利亚研究委员会基金, Electrocoagulation as an efficient method for wastewater treatment
Ø 国家自然科学基金面上项目, 电化学氧化降解有机污染物过程中聚合物膜的形成及防止措施
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研究成果
在Nature Communications等期刊发表SCI论文300余篇(其中IF>10的120余篇),总计引用超17000次。撰写英文专著1部,专著章节6个、教材3本。授权国家发明专利30项。连续9年入选爱思唯尔中国高被引学者(环境科学)、ESI前1%作者,H 因子为73。
部分代表性论文如下:
1. Zhang Q.Z., Zhou M.H.*, Ren G.B., Li Y.W., Li Y.C., Du X.D. Highly efficient electrosynthesis of hydrogen peroxide on a superhydrophobic three-phase interface by natural air diffusion. Nat. Comm., 2020, 11: 1731.
2. Li S ,Wang W ,Wu H , et al. Performance enhancement and mechanism of electroenhanced peroxymonosulfate activation by single-atom Fe catalyst modified electrodes. [J]. Proceedings of the National Academy of Sciences of the United States of America, 2024, 121 (37): e2404965121.
3. Du X.D., Zhou M.H.* Strategies to enhance catalytic performance of metal-organic frameworks in sulfate radical-based advanced oxidation processes for organic pollutants removal. Chem. Eng. J., 2021, 403: 126346.
4. Tian Y.S., Zhou M.H.*, Pan Y.W, Du X.D., Wang Q. MoS2 as highly efficient co-catalyst enhancing the performance of Fe0 based electro-Fenton process in degradation of sulfamethazine: approach and mechanism. Chem. Eng. J., 2021, 403: 126361.
5. Cai J.J., Zhou M.H.*, Du X.D., Xu X. Enhanced mechanism of 2,4-dichlorophenoxyacetic acid degradation by electrochemical activation of persulfate on Blue-TiO2 nanotubes anode. Sep. Purif. Technol., 2021, 254: 117560.
6. Zhang Q.Z., Zhou M.H.*, Lang Z.C., Du X.D., Cai J.J., Han L.J. Dual strategies to enhance mineralization efficiency in innovative electrochemical advanced oxidation processes using natural air diffusion electrode: improving both H2O2 production and utilization efficiency. Chem. Eng. J. 2021, 413: 127564.
7. Li Y.W., Liu L.W., Zhang Q.Z., Tang Y.P., Zhou M.H*. Highly cost-effective removal of 2,4-dichlorophenoxiacetic acid by peroxi-coagulation using natural air diffusion electrode. Electrochim. Acta, 2021, 377: 138079.
8. Su P., Fu W.Y., Du X.D., Song G., Zhou M.H.* Confined Fe0@CNTs for highly efficient and super stable activation of persulfate over wide pH ranges: radicals and non-radical co-catalytic mechanism. Chem. Eng. J., 2021, 420: 129446.
9. Li M., Zhou M.H.*, Tian X.Y., Tan C.L., Gu T.Y. Enhanced bioenergy recovery and nutrient removal from swine wastewater using an airlift-type photosynthetic microbial fuel cell. Energy, 2021, 226: 120422.
10. Cai J.J., Zhou M.H.*, Zhang Q.Z., Tian Y.S., Song G. The radical and non-radical oxidation mechanism of electrochemically activated persulfate process on different cathodes in divided and undivided cell. J. Hazard. Mater., 2021, 416: 125804.
11. Li Y.W., Liu L.W., Zhang Q.Z., Su Y., Zhou M.H.* Hybrid electro-Fenton and peroxi-coagulation process for high removal of 2,4-dichlorophenoxiacetic acid with low iron sludge generation. Electrochim. Acta, 2021, 382: 138304.
12. Ren G.B., Zhou M.H.*, Zhang Q.Z., Xu X., Li Y.C., Su P. A novel stacked flow-through electro-Fenton reactor as decentralized system for the simultaneous removal of pollutants (COD, NH3-N and TP) and disinfection from domestic sewage containing chloride ions. Chem. Eng. J., 2020, 387: 124037.
13. Cai J.J., Zhou M. H.*, Pan Y.W., Lu X. Y. Degradation of 2,4-dichlorophenoxyacetic acid by anodic oxidation and electro-Fenton using BDD anode: influencing factors and mechanism. Sep. Purif. Technol. 2020, 230: 115867.
14. Yang W.L., Oturan N., Raffye S., Zhou M.H.*, Oturan M.A.* Electrocatalytic generation of homogeneous and heterogeneous hydroxyl radicals for cold mineralization of anti-cancer drug Imatinib. Chem. Eng. J. 2020, 383: 123155.
15. Xu X., Cai J.J., Zhou M.H.*, Du X.D., Zhang Y*. Photoelectrochemical degradation of 2,4-dichlorophenoxyacetic acid using electrochemically self-doped blue TiO2 nanotube arrays with formic acid as electrolyte. J. Hazard. Maters. 2020, 382: 121096.
16. Pan Y.W., Zhou M.H.*, Wang Q., Cai J.J., Tian Y.S., Zhang Y.* EDTA, oxalate, and phosphate ions enhanced reactive oxygen species generation and sulfamethazine removal by zero-valent iron. J. Hazard. Mater. 2020, 391: 122210.
17. Lang Z.C., Zhou M.H.*, Zhang Q.Z., Ying X.Y., Li Y.W. Comprehensive treatment of marine aquaculture wastewater by a cost-effective flow-through electro-oxidation process. Sci. Total. Environ. 2020, 722: 137812.
18. Yang W.L., Zhou M.H.*, Oturan N., Bechelany M., Cretin M., Oturan M.A*. Highly efficient and stable FeIIFeIII LDH carbon felt cathode for removal of pharmaceutical ofloxacin at neutral pH. J. Hazard. Mater. 2020, 393: 122513.
19. Su P., Zhou M.H.*, Song G., Du X.D., Lu X.Y. Efficient H2O2 generation and spontaneous •OH conversion for in-situ phenol degradation on nitrogen-doped graphene: pyrolysis temperature regulation and catalyst regeneration mechanism. J. Hazard. Mater. 2020, 397: 122681.
20. Cai J.J., Zhou M.H.*, Xu X., Du X.D. Stable boron and cobalt co-doped TiO2 nanotubes anode for efficient degradation of organic pollutants. J. Hazard. Mater. 2020, 396: 122723.
21. Pan Y.W., Wang Q., Zhou M.H.*, Cai J.J., Tian Y.S., Zhang Y*. Kinetic and mechanism study of UV/pre-magnetized-Fe0/oxalate for removing sulfamethazine. J. Hazard. Mater. 2020, 398: 122931.
22. Du X.D., Fu W.Y., Su P., Cai J.J., Zhou M.H*. Internal-micro-electrolysis-enhanced heterogeneous electro-Fenton process catalyzed by Fe/Fe3C@PC core-shell hybrid for sulfamethazine degradation. Chem. Eng. J., 2020, 398: 125681.
23. Pan Y.W., Bu Z.Y., Sang C.H., Guo H.J., Zhou M.H.*, Zhang Y., Tian Y.S., Cai J.J., Wang W.* EDTA enhanced pre-magnetized Fe0/H2O2 process for removing sulfamethazine at neutral pH. Sep. Purif. Technol., 2020, 250: 117281.
24. Su P., Zhou M.H.*, Ren G.B., Lu X.Y., Du X.D., Song G. A carbon nanotube-confined iron modified cathode with prominent stability and activity for heterogeneous electro-Fenton reactions. J. Mater. Chem. A, 2019, 7: 24408–24419.
25. Zhang Y., Zhou M.H.* A critical review of the application of chelating agents to enable Fenton and Fenton-like reactions at high pH values. J. Hazard. Mater., 2019, 362: 436-450.
26. Ren G.B., Zhou M.H.*, Zhang Q.Z., Xu X., Li Y.C., Su P., Paidar M., Bouzek K. Cost-efficient improvement of coking wastewater biodegradability by multi-stages flow through peroxi-coagulation under low current load. Water Res., 2019, 154: 336-348.
27. Su P., Zhou M.H.*, Lu X.Y., Yang W.L., Ren G.B., Cai J.J. Electrochemical catalytic mechanism of N-doped graphene for enhanced H2O2 yield and in-situ degradation of organic pollutant. Appl. Catal. B-Environ., 2019, 245: 583-595.
28. Pan Y.W., Zhang Y., Zhou M.H.*, Cai J.J., Tian Y.S. Enhanced removal of antibiotics from secondary wastewater effluents by novel UV/pre-magnetized Fe0/H2O2 process. Water Res., 2019, 153: 144-159.
29. Li M., Zhou M.H.*, Tian X. Y., Tan C. L., McDaniel C. T., Hassett D. J., Gu. T.Y*. Microbial fuel cell (MFC) power performance improvement through enhanced microbial electrogenicity. Biotechnol. Adv., 2018, 36: 1316-1327.
30. Yang W., Zhou M.H.*, Liang L. Highly efficient in-situ metal-free electrochemical advanced oxidation process using graphite felt modified with N-doped graphene. Chem. Eng. J., 2018, 338: 700-708.
31. Zhang C., Ren G.B., Wang W., Yu X.M., Yu M.K., Zhang Q.Z., Zhou M.H*. A new type of continuous-flow heterogeneous electro-Fenton reactor for Tartrazine degradation. Sep. Purif. Technol., 2019, 208: 76-82.
32. Li M., Zhou M.H.*, Tan C.L., Tian X.Y. Enhancement of CO2 biofixation and bioenergy generation using a novel airlift type photosynthetic microbial fuel cell. Bioresour. Technol., 2019, 272: 501-509.
33. Zhang Y., Xu X., Pan Y.W., Xu L.T., Zhou M.H*. Pre-magnetized Fe0 activated persulphate for the degradation of nitrobenzene in groundwater. Sep. Purif. Technol., 2019, 212: 555-562.
34. Yang W.L., Zhou M.H.*, Oturan N., Li Y.W., Su P., Oturan M.A.* Enhanced activation of hydrogen peroxide using nitrogen doped graphene for effective removal of herbicide 2,4-D from water by iron-free electrochemical advanced oxidation. Electrochim. Acta, 2019, 297: 582-592.
35. Zhang Y.^, Liu M.M.^, Zhou M.H.*, Yang H.J., Liang L., Gu T.Y*.Microbial fuel cell hybrid systems for wastewater treatment and bioenergy production: Synergistic effects, mechanisms and challenges. Renewable & Sustainable Energy Reviews, 2019, 103: 13-29.
36. Pan Y.W., Zhang Y., Zhou M.H.*, Cai J.J., Tian Y.S. Enhanced removal of emerging contaminants using persulfate activated by UV and pre-magnetized Fe0. Chem. Eng. J., 2019, 361: 908-918.
37. Pan Y.W., Zhang Y., Zhou M.H.*, Cai J.J., Tian Y.S. Enhanced removal of antibiotics from secondary wastewater effluents by novel UV/pre-magnetized Fe0/H2O2 process. Water Res., 2019, 153: 144-159.
38. Su P., Zhou M.H.*, Lu X.Y., Yang W.L., Ren G.B., Cai J.J. Electrochemical catalytic mechanism of N-doped graphene for enhanced H2O2 yield and in-situ degradation of organic pollutant. Appl. Catal. B-Environ., 2019, 245: 583-595.
39. Ren G.B., Zhou M.H.*, Su P., Yang W.L., Lu X.Y., Zhang Y.Q. Simultaneous sulfadiazines degradation and disinfection from municipal secondary effluent by a flow-through electro-Fenton process with graphene-modified cathode. J. Hazard. Maters., 2019, 368: 830-839.
40. Zhang Y.Q., Zuo S.J., Zhang Y., Ren G.B., Pan Y.W., Zhang Q.Z., Zhou M.H*. Simultaneous removal of tetracycline and disinfection by a flow-through electro-peroxone process for reclamation from municipal secondary effluent. J. Hazard. Maters., 2019, 368: 771-777.
41. Ren G.B., Zhou M.H.*, Zhang Q.Z., Xu X., Li Y.C., Su P., Paidar M., Bouzek K. Cost-efficient improvement of coking wastewater biodegradability by multi-stages flow through peroxi-coagulation under low current load. Water Res., 2019, 154: 336-348.
42. Li M., Zhou M.H.*, Luo J.M., Tan C.L., Tian X.Y., Su P., Gu T.Y. Carbon dioxide sequestration accompanied by bioenergy generation using a bubbling-type photosynthetic algae microbial fuel cell. Bioresour. Technol. 2019, 280: 95-103.
43. Yang W.L., Zhou M.H.*, Oturan N., Li Y.W., Oturan M.A.* Electrocatalytic destruction of pharmaceutical imatinib by electro-Fenton process with graphene-based cathode. Electrochim. Acta 2019, 305: 285-294.
44. Li K.R., Zhou M.H.*, Liang L., Su P., Jiang L.L., Wang W.* Ultrahigh-surface-area activated carbon aerogels derived from glucose for high-performance organic pollutants adsorption. J. Colloid & Interf. Sci., 2019, 546: 333-343.
45. Zhang Y.Q.^, Zuo S.J.^, Zhou M.H.*, Liang L., Ren G.B. Removal of tetracycline by coupling of flow-through electro-Fenton and in-situ regenerative active carbon felt adsorption. Chem. Eng. J., 2018, 335: 685-692.
46. Tian X., Zhou M.*, Li M., Tan C., Liang L. Nitrogen-doped activated carbon as metal-free oxygen reduction catalyst for cost-effective rolling-pressed air-cathode in microbial fuel cells. Fuel, 2018, 223: 422-430.
47. Yang W., Zhou M.H.*, Liang L. Highly efficient in-situ metal-free electrochemical advanced oxidation process using graphite felt modified with N-doped graphene. Chem. Eng. J., 2018, 338: 700-708.
48. Pan Y.W., Zhou M.H. *, Cai J.J., Li X., Wang W., Li B., Sheng X.J., Tang Z. X. Significant enhancement in treatment of salty wastewater by pre-magnetization Fe0/H2O2 process. Chem. Eng. J., 2018, 339: 411-423.
49. Nidheesh P.V., Zhou M.H., Oturan M. A*. An overview on the removal of synthetic dyes from water by electrochemical advanced oxidation processes. Chemosphere, 2018, 197: 210-227.
50. Liang L., Zhou M.H.*, Li K.R., Jiang L.L., Facile and fast polyaniline-directed synthesis of monolithic carbon cryogels from glucose. Micropor. Mesopor. Mater., 2018, 265: 26-34.
51. Ren G.B., Zhou M.H.*, Su P., Liang L., Yang W.L., Mousset E. Highly energy-efficient removal of acrylonitrile by peroxi–coagulation with modified graphite felt cathode: influence factors, possible mechanism. Chem. Eng. J., 2018, 343: 467-476.
52. Pan Y.W., Zhou M.H.*, Zhang Y., Cai J.J., Li B., Sheng X.J. Enhanced degradation of Rhodamine B by pre-magnetized Fe0/PS process: Parameters optimization, mechanism and interferences of ions. Sep. Purif. Technol., 2018, 203: 66-74.
53. Cai J.J., Zhou M.H.*, Liu Y., Savall A., Serrano K.G*. Indirect electrochemical oxidation of 2,4-Dichlorophenoxyacetic acid using electrochemically-generated persulfate. Chemosphere, 2018, 204: 163-169.
54. Gu T.Y.*, Rastegar S.O., Mousavi S.M., Li M., Zhou M. Advances in bioleaching for recovery of metals and bioremediation of solid wastes. Bioresour. Technol., 2018, 261: 428-440.
55. Li X., Zhou M.H.*, Pan Y. W. Enhanced degradation of 2,4-dichlorophenoxyacetic acid by pre-magnetization Fe-C activated persulfate: Influential factors, mechanism and degradation pathway. J. Hazard. Mater. 2018, 353: 454-465.
56. Zhang Y.Q., Zuo S.J., Zhang Y., Li M., Cai J.J., Zhou M.H.* Disinfection of simulated ballast water by a flow-through electro-peroxone process. Chem. Eng. J. 2018, 348: 485-493.
57. Li M., Zhou M.H.*, Tian X. Y., Tan C. L., McDaniel C. T., Hassett D. J., Gu. T.Y*. Microbial fuel cell (MFC) power performance improvement through enhanced microbial electrogenicity. Biotechnol. Adv., 2018, 36: 1316-1327.
58. Tian X.Y., Zhou M.H.*, Tan C.L., Li M., Liang L., Li K.R., Su P. KOH activated N-doped novel carbon aerogel as efficient metal-free oxygen reduction catalyst for microbial fuel cells. Chem. Eng. J., 2018, 348: 775-785.
59. Yang H.J., Zhou M.H.*, Yang W.L., Ren G.B., Ma L. Rolling-made gas diffusion electrode with carbon nanotube for electro-Fenton degradation of acetylsalicylic acid. Chemosphere, 2018, 206: 439-446.
60. Luo J.M.*, Wang T.T., Li X., Yang Y.N., Zhou M.H.*, Li M., Yan Z.L. Enhancement of bioelectricity generation via heterologous expression of IrrE in Pseudomonas aeruginosa-inoculated MFCs. Biosen. Bioelectron. 2018, 117: 23-31.
61. Liang L., Zhou M.H.*, Tan C.L., Tian X.Y., Li K.R. Easily tunable hydrogel-derived heteroatom-doped hierarchically porous carbons as multifunctional materials for supercapacitors, CO2 capture and dye removal. Micropor. Mesopor. Mater., 2018, 271: 92-99.
62. Ganiyu S.O.*, Zhou M.H., Martinez-Huitle C*. Heterogeneous electro-Fenton and photoelectro-Fenton processes: A critical review of fundamental principles and application for water/wastewater treatment. Appl. Catal. B: Environ., 2018, 235: 103-129.
63. Oturan M. A*, Nidheesh P.V., Zhou M.H. Electrochemical advanced oxidation processes for the abatement of persistent organic pollutants. Chemosphere, 2018, 209: 17-19.
64. Jiang L.L.^, Zhang Y.^, Zhou M.H., Liang L., Li K. R. Oxidation of Rhodamine B by persulfate activated with porous carbon aerogel through a non-radical mechanism. J. Hazard. Mater. 2018, 358: 53-61.
65. Liang L., Zhou M.H.*, Yang W.L., Jiang L.L. Enhanced activation of persulfate by carbohydrate-derived carbon cryogels for effective removal of organic pollutants. Chem. Eng. J., 2018, 352: 673-681.
66. Pan Y., Zhang Y., Zhou M.H.*, Cai J.J., Li X., Tian Y.S. Synergistic degradation of antibiotic sulfamethazine by novel pre-magnetized Fe0/PS process enhanced by ultrasound. Chem. Eng. J., 2018, 354: 777-789.
67. Cai J.J., Zhou M.H.*, Yang W.L., Pan Y.W., Lu X.Y. K.G. Serrano. Degradation and mechanism of 2,4-Dichlorophenoxyacetic acid (2,4-D) by thermally activated persulfate oxidation. Chemosphere, 2018, 212: 784-793.
68. Li X., Zhou M.H.*, Pan Y. W. Degradation of diclofenac by H2O2 activated with pre-magnetization Fe0: Influencing factors and degradation pathways. Chemosphere, 2018, 212: 853-862.
69. Yang W., Zhou M.H.*, Cai J. J., Liang L., Ren G. B. Ultrahigh yield of hydrogen peroxide on graphite felt cathode modified with electrochemically exfoliated graphene. J. Mater. Chem. A, 2017, 5: 8070–8080.
70. Zhang H.M., Xu W., Fan Z., Liu X., Wu Z.C*., Zhou M.H*. Simultaneous removal of phenol and dichromate from aqueous solution through a phenol-Cr(VI) coupled redox fuel cell reactor. Sep. Purif. Technol., 2017, 172: 152-157.
71. Li X., Zhou M.H.*, Pan Y.W., Xu L.T. Pre-magnetized Fe0/persulfate for notably enhanced degradation and dechlorination of 2,4-dichlorophenol. Chem. Eng. J., 2017, 307: 1092-1104.
72. Li X., Zhou M.H.*, Pan Y.W., Xu L.T., Tang Z.X. Highly efficient advanced oxidation processes (AOPs) based on pre-magnetization Fe0 for wastewater treatment. Sep. Purif. Technol., 2017, 178: 49-55.
73. Pan Y.W., Zhou M.H.*, Li X., Xu L.T., Tang Z.X., Sheng X.J., Li B. Highly efficient persulfate oxidation process activated with premagnetization Fe0. Chem. Eng. J. 2017, 318: 50-56.
74. Liu M.M., Zhou M.H.*, Yang H.J., Ren G.B., Zhao Y.Y. Titanium dioxide nanoparticles modified three dimensional ordered macroporous carbon for improved energy output in microbial fuel cells. Electrochim. Acta 2016, 190: 463-470.
75. Liu M.M., Zhou M.H.*, Ma L., Yang H.J., Zhao Y.Y. Architectural design of hierarchically meso-macroporous carbon for microbial fuel cells anode. RSC Adv., 2016, 6: 27993-27998.
76. Ma L., Zhou M.H.*, Ren G.B., Yang W.L., Liang L. A highly energy-efficient flow-through electro-Fenton process for organic pollutants degradation. Electrochim. Acta 2016, 200: 222-230.
77. Ren G.B., Zhou M.H.*, Liu M.M., Ma L., Yang H.J. A novel vertical-flow electro-Fenton reactor for organic wastewater treatment. Chem. Eng. J. 2016, 298: 55-67.
78. Pan Y.W., Zhou M.H.*, Li X., Xu L.T., Tang Z.X., Liu M.M. Novel Fenton-like process (pre-magnetized Fe0/H2O2) for efficient degradation of organic pollutants. Sep. Purif. Technol., 2016, 169: 83-92.
79. Liang L, An Y.R., Yu F.K., Liu M.M, Ren G.B., Zhou M.H*. Novel rolling-made gas-diffusion electrode loading trace transition metal for efficient heterogeneous electro-Fenton-like. J. Environ. Chem. Eng., 2016, 4: 4400-4408.
80. Yu X.M., Zhou M.H.*, Ren G.B., Ma L. A novel dual gas diffusion electrodes system for efficient hydrogen peroxide generation used in electro-Fenton. Chem. Eng. J., 2015, 263: 92-100.
81. Zhang C., Zhou M.H.*, Ren G.B., Yu X.M., Ma L., Yang J., Yu F.K. Heterogeneous electro-Fenton using modified iron-carbon as catalyst for 2,4-dichlorophenol degradation: Influence Factors, mechanism and degradation pathway. Water Res., 2015, 70: 414-424.
82. Zhang C., Zhou M.H.*, Yu X.M., Ma L., Yu F.K. Modified iron-carbon as heterogeneous electro-Fenton catalyst for organic pollutant degradation in near neutral pH condition: Characterization, degradation activity and stability. Electrochim. Acta, 2015, 160: 254-262.
83. Luo J.M.*, Li M., Zhou M.H.*, Hu Y.S. Characterization of a novel strain phylogenetically related to Kocuria rhizophila and its chemical modification to improve performance of microbial fuel cells. Biosens. Bioelectron., 2015, 69: 113-120.
84. Yu F.K., Zhou M.H.*, Yu X.M. Cost-effective electro-Fenton using modified graphite felt that dramatically enhanced on H2O2 electro-generation without external aeration. Electrochim. Acta, 2015, 163: 182-189.
85. Yang W.L., Han H.X., Zhou M.H.*, Yang J. Simultaneous electricity generation and tetracycline removal in continuous flow electrosorption driven by microbial fuel cells. RSC Adv. 2015, 5: 49513-49520.
86. Yang H.J., Zhou M.H.*, Liu M.M., Yang W.L., Gu T.Y. Microbial fuel cells for biosensor applications. Biotechnol. Letts. 2015, 37: 2357-2364.
87. Liu M.M., Zhou M.H.*, Yang H. J., Zhao Y. Y., Hu Y.S. A cost-effective polyurethane based activated carbon sponge anode for high-performance microbial fuel cells. RSC Adv. 2015, 5: 84269 - 84275.
88. Hu Z., Zhou M.*, Zhou L., Li Y., Zhang C. Effect of matrix on the electrochemical characteristics of TiO2 nanotube arrays based PbO2 electrode for pollutant degradation. Environ. Sci. Pollut. Res., 2014, 21: 8476–8484.
89. He H., Zhou M.*, Yang J., Hu Y., Zhao Y. Simultaneous wastewater treatment, electricity generation and biomass production by an immobilized photosynthetic algal microbial fuel cell. Bioproc. Biosystem. Eng., 2014, 37: 873–880.
90. Thiam A., Zhou M.H.*, Sirés, I.*, Brillas, E. Two-step mineralization of Tartrazine solutions: Study of parameters and by-products during the coupling of electrocoagulation with electrochemical advanced oxidation processes. Appl. Catal. B. 2014, 150-151: 116-125.
91. Thiam, A., Zhou, M.*, Brillas, E., Sirés, I.*, A first pre-pilot system for the combined treatment of dye pollutants by electrocoagulation/EAOPs. J. Chem. Technol. Biotechnol. 2014, 89: 1136–1144.
92. Jiang Y., Hu Z.X., Zhou M.H.*, Zhou L., Xi B*. Efficient degradation of p-nitrophenol by electro-oxidation on Fe doped Ti/TiO2 nanotube/PbO2 anode. Sep. Purif. Technol., 2014, 128: 67-71.
93. Yu X.M., Zhou M.H.*, Hu Y.S., Groenen Serrano K. Yu F.K. Recent updates on electrochemical degradation of refractory organic pollutants using BDD anode: a mini review. Environ. Sci. Pollut. Res., 2014, 21: 8417–8431.
94. Zhou L., Zhou M.*, Hu Z., Bi Z., Serrano K.G. Chemically modified graphite felt as an efficient cathode in electro-Fenton for p-nitrophenol degradation. Electrochim. Acta, 2014, 140: 376-383.
95. Yu F., Zhou M.*, Zhou L., Peng R. A novel electro-Fenton process with H2O2 generation in a rotating disk reactor for organic pollutant degradation. Environ. Sci. Technol. Letts., 2014, 1 (7): 320–324.
96. Wang Q., Jin T., Hu Z.X., Zhou L., Zhou M.H*. TiO2-NTs/SnO2-Sb anode for efficient electrocatalytic degradation of organic pollutants: Effect of TiO2-NTs architecture. Sep. Purif. Technol., 2013, 102: 180-186.
97. Zhou M. H., Wang H. Y., Hassett D. J., Gu T.Y.* Recent advances in microbial fuel cells (MFCs) and microbial electrolysis cells (MECs) for wastewater treatment, bioenergy and bioproducts. J. Chem. Technol. Biotechnol., 2013, 88(4): 508-518.
98. Jin T., Zhou L., Luo J.M., Yang J., Zhao Y.Y., Zhou M.H*. Hydrazine hydrate chemical reduction as an effective anode modification method to improve the performance of microbial fuel cells. J. Chem. Technol. Biotechnol., 2013, 88: 2075-2081.
99. Zhou L., Hu Z.X., Zhang C., Bi. Z.H., Jin T., Zhou M. H*. Electro-generation of hydrogen peroxide for electro-Fenton system by oxygen reduction using chemically modified graphite felt cathode. Sep. Purif. Technol., 2013, 111: 131-136.
100. Wang X., Jin X., Zhou M.H.*, Liu Y., Zhang X.D. Decolorization of Acid orange 7 with DC diaphragm glow discharge. Electrochim. Acta 2013, 103: 237-242.
101. Luo J.M.*, Yang J., He H.H., Jin T., Zhou L., Wang M., Zhou M.H*. A new electrochemically active bacterium phylogenetically related to Tolumonas osonensis and power performance in MFCs. Bioresour. Technol., 2013, 139: 141-148.
102. Zhang C., Jiang Y.H.*, Li Y.L., Hu Z.X., Zhou L., Zhou M.H*. Three-dimensional electrochemical process for wastewater treatment: A general review. Chem. Eng. J. 2013, 228: 455-467.
103. Yang J., Zhao Y.Y., Zhang C., Hu Y.S., Zhou M.H*. Electrosorption driven by microbial fuel cells without electric grid energy consumption for simultaneous phenol removal and wastewater treatment. Electrochem. Commun. 2013, 34: 121-124.
104. Zhou M.H.*, Yang J., Wang H.Y., Jin T., Xu D., Gu T*. Microbial fuel cells (MFCs) and microbial electrolysis cells (MECs) for the production of bioelectricity and biomaterials. Environ. Technol., 2013, 34(13–14): 1915–1928.
105. Zhou L. Zhou M.*, Zhang C., Jiang Y., Bi Z.H., Yang J. Electro-Fenton degradation of p-nitrophenol using the anodized graphite felts. Chem. Eng. J., 2013, 233: 185-192.
106. Wang X., Jin X., Zhou M.*, Chen Z., Deng K. Reduction of Cr(VI) in aqueous solution with DC diaphragm glow discharge. Electrochem. Acta. 2013, 112: 692- 697.
107. Yang J., Zhou M.H.*, Zhao Y.Y., Zhang C., Hu Y.S. Electrosorption driven by microbial fuel cells to remove phenol without external power supply. Bioresour. Technol., 2013, 150: 271-277.
108. Zhou M. H.*, Chi M. L., Wang H. Y., Jin T. Anode modification by electrochemical oxidation: An alternative to improve the performance of microbial fuel cells. Biochem. Eng. J., 2012, 60, 151-155.
109. Jin X. L., Zhang H. M., Wang X. Y., Zhou M. H*. An improved multi-anode contact glow discharge electrolysis reactor for dye discoloration. Electrochim. Acta, 2012, 59, 474-478.
110. Zhou M.H.*, Tan Q. Q., Wang Q., Jiao Y. L., Oturan N., Otruan M. A. Degradation of organics in reverse osmosis concentrate by electro-Fenton process. J. Hazard. Mater., 2012, 215-216: 287-293.
111. Zhou M. H*, He H. H, Jin T., Wang H.Y. Power generation enhancement in novel microbial carbon capture cells with immobilized Chlorella vulgaris. J. Power Sources, 2012, 214: 216-219.
112. Liu L., He H. H., Zhang C., Wang Q., Zhou M. H*. Treatment of reverse osmosis concentrates using a three-dimensional electrode reactor. Current Organic Chemistry, 2012, 16: 2091-2096.
113. Wang H. Y., Zhou M. H., Jin X. L. Application of glow discharge plasma for wastewater treatment. Electrochim. Acta, 2012, 83: 501-506.
114. Jin T., Luo J.M., Yang J., Zhou L., Zhao Y.Y., Zhou M.H*. Coupling of anodic and cathodic modification for increased power generation in microbial fuel cells. J. Power Sources 2012, 219: 358-363.
115. Zhang A. Y., Zhou M. H.*, Zhou Q. X*. A combined photocatalytic determination system for chemical oxygen demand with a highly oxidative reagents. Anal. Chim. Acta, 2011, 686: 133-143.
116. Zhang A. Y., Zhou M. H.*, Han L., Zhou Q*. The combination of rotating disk photocatalytic reactor and TiO2 nanotube arrays for environmental pollutants removal. J. Hazard Maters., 2011, 186: 1374-1383.
117. Zhou M. H.*, Chi M. L., Luo J. M., He H. H., Jin T. An overview of electrode materials in microbial fuel cells. J. Power Sources, 2011, 196: 4427-4435.
118. Zhou M. H.*, Särkkä H., Sillanpää M. A comparative experimental study on methyl orange degradation by electrochemical oxidation on BDD and MMO electrodes. Sep. Purif. Technol., 2011, 78: 290–297.
119. Zhou M.H.*, Liu L., Jiao Y. L., Wang Q., Tan Q. Q. Treatment of high-salinity reverse osmosis concentrate by electrochemical oxidation on BDD and DSA electrodes. Desalination, 2011, 277, 201-206.
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学校介绍
南开大学是教育部直属重点综合性大学,是敬爱的周恩来总理的母校。新中国成立以来,学校发展始终得到党和国家的亲切关怀。毛泽东主席题写校名、亲临视察;周恩来总理三回母校指导;邓小平同志会见数学大师陈省身,批示成立南开数学研究所;江泽民同志、胡锦涛同志先后视察南开。特别是党的十八大以来,习近平总书记多次对南开的发展给予肯定,并对相关工作回信和勉励,更在百年校庆之际亲临南开视察。
南开大学由严修、张伯苓秉承教育救国理念创办,肇始于1904年,成立于1919年。1937年校园遭侵华日军炸毁,学校南迁。1938年与北京大学、清华大学合组西南联合大学,被誉为“学府北辰”。1946年回津复校并改为国立。
新中国成立后,经历高等教育院系调整,成为文理并重的全国重点大学。改革开放以来,天津对外贸易学院、中国旅游管理干部学院相继并入,经教育部与天津市共建支持,学校发展成为国家“211工程”和“985工程”重点建设的综合性研究型大学。2015年9月,新校区建成启用后,初步形成了八里台校区、津南校区、泰达学院“一校三区”办学格局。2017年9月,入选国家42所世界一流大学建设高校,且为36所A类高校之一。
南开大学坚持“允公允能,日新月异”的校训,弘扬“爱国、敬业、创新、乐群”的传统和“文以治国、理以强国、商以富国”的理念,以“知中国,服务中国”为宗旨,以杰出校友周恩来为楷模,作育英才,繁荣学术,强国兴邦,传承文明,努力建设世界一流大学。
南开大学占地443.12万平方米,其中八里台校区占地121.60万平方米,津南校区占地245.89万平方米,泰达学院占地6.72万平方米。校舍建筑总面积195.19万平方米。按照“独立办学、紧密合作”的原则,与天津大学全面合作办学。
南开大学是国内学科门类齐全的综合性、研究型大学之一。在长期办学过程中,形成了文理并重、基础宽厚、突出应用与创新的办学特色。有专业学院26个,学科门类覆盖文、史、哲、经、管、法、理、工、农、医、教、艺等。
南开大学拥有一支公能兼备、业务精湛、奋发有为、充满活力的师资队伍。有专任教师2202人。其中,博士生导师885人、硕士生导师783人,教授898人、副教授857人。
南开大学具备培养学士、硕士和博士的完整教育体系。有在校学生31418人,其中本科生17005人,硕士研究生10299人,博士研究生4114人。有网络专科学生40230人,网络本科学生73029人。
学校积极构建和发展适应21世纪经济社会发展和人才培养需要的学科体系,有本科专业93个(其中国家级特色专业18个),硕士学位授权一级学科11个,硕士专业学位授权点27个,博士学位授权一级学科31个,不在一级学科覆盖下的二级博士点1个,博士后科研流动站28个。有国家“双一流”建设学科5个,一级学科国家重点学科6个(覆盖35个二级学科),二级学科国家重点学科9个,一级学科天津市重点学科32个,国家级一流本科专业建设点21个,省级一流本科专业建设点2个。有国家重点实验室2个,国家工程研究中心1个,国家地方联合工程研究中心1个,2011协同创新中心3个。教育部重点实验室7个,教育部工程研究中心3个,教育部国际合作联合实验室2个,国家环境保护重点实验室1个,国家人权教育与培训基地1个,教育部人文社会科学重点研究基地6个,省部共建协同创新中心1个,教育部国别和区域研究基地7个(培育基地1个、备案基地6个),示范性国家国际科技合作基地4个。国家级实验教学示范中心5个,国家级虚拟仿真实验教学中心2个,国家虚拟仿真实验教学项目2项,国家基础学科人才培养和科学研究基地9个,国家教材建设重点研究基地1个,国家大学生文化素质教育基地1个,中华传统文化传承基地2个,国家创新人才培养示范基地1个。天津市重点实验室20个,天津市工程技术中心4个,天津市普通高等学校实验教学示范中心14个,天津市普通高等学校实验教学示范中心建设单位1个,天津市国际科技合作基地22个,天津市人文社科重点研究基地9个,天津市高校智库8个,天津市社科实验室5个,天津市爱国主义教育基地1个。
有中国科学院院士11人,中国工程院院士4人,发展中国家科学院院士8人,教育部“长江学者奖励计划”特聘教授44人、青年学者19人,“国家杰出青年科学基金”获得者57人、“国家优秀青年科学基金”获得者39人,国家“万人计划”领军人才27人、青年拔尖人才15人,国家“百千万人才工程”入选者30人,教育部“跨世纪人才基金”获得者21人、“新世纪优秀人才支持计划”入选者158人,国家级有突出贡献的专家22人,国务院学位委员会学科评议组成员16人,国家自然科学基金创新研究群体负责人6人,“国家高技术研究发展计划(863计划)”首席科学家3人,“国家重点基础研究发展计划(973计划)”首席科学家15人,国家重点研发计划项目负责人24人。国家级教学名师奖获得者7人,国家级教学团队9个,教育部“高校青年教师奖”获得者8人。天津市杰出人才8人,天津市“人才发展特殊支持计划”领军人才3人、青年拔尖人才11人、高层次创新创业团队带头人11人,天津市有突出贡献专家7人,天津市杰出津门学者3人,天津市“131”创新人才培养工程第一层次人选63人、创新型人才团队带头人17人,“天津市杰出青年科学基金”获得者40人,天津市级教学名师奖获得者35人,天津市级教学团队18个。
南开大学既是教学中心,又是科研中心,取得了一批国内外公认的优秀成果。2019年,周其林院士领衔完成的“高效手性螺环催化剂的发现”项目获国家自然科学奖一等奖。2007—2018年以第一单位获得国家自然科学二等奖4项,国家科技进步二等奖1项,国家技术发明二等奖1项。获国家教学成果奖46项,国家级精品资源共享课31门,国家级精品视频公开课15门,国家级一流本科课程31门,中国专利优秀奖1项,中国青年科技奖2项,全国百篇优秀博士论文累计入选20篇。2018年以来,南开学者团队以第一完成单位在Science上发表研究论文6篇。
南开大学秉承“知中国,服务中国”的优良传统,立足“四个服务”职责使命,聚焦“一带一路”、京津冀协同发展、雄安新区建设等国家和区域发展战略,积极发挥学科、人才和技术优势,努力为国家和地方经济社会发展服务。习近平新时代中国特色社会主义思想研究院、21世纪马克思主义研究院、亚太经济合作组织研究中心、中国新一代人工智能发展战略研究院、经济与社会发展研究院、滨海开发研究院、人权研究中心、津南研究院、统计研究院、生态文明研究院等研究机构是国家有关部委和地方政府的“智囊团”和“人才库”。学校按照“国家急需,世界一流”的原则,全面对接“创新驱动发展”战略、“中国制造2025”等的实施,积极推动各类协同创新中心和若干高层次交叉科学中心建设,与一批高校、企业、科研院所、政府部门建立了紧密合作关系。
南开大学重视学生德、智、体、美、劳全面发展,构建南开特色的“公能”素质教育体系,探索“课堂教学-校园文化-社会实践”三位一体育人模式。以“注重素质、培养能力、强化基础、拓宽专业、严格管理、保证质量”为教学指导思想,实行弹性学制、学分制、主辅修制、双学位制。注重培育优良校风,大力加强校园文化建设,为学生营造丰富高雅、活泼向上的成长氛围。推进创新创业教育,开办“创业班”,推进“南开大学学生创新创业实践基地”建设,提升学生创新能力,助力学生创业计划落地。大力开展“师生同行”社会实践,搭建师生“受教育、长才干、作贡献”的互动平台。南开毕业生以专业基础扎实、综合素质全面、富于开拓精神和实践能力而受到社会各界青睐。
南开大学有着广泛的国际影响,与320多所国际知名大学和国际学术机构建立了合作与交流关系;有专兼职外国专家400余人,以及来自114个国家和地区的2000余名留学生在校学习;承建了英国格拉斯哥大学孔子学院等8所海外孔子学院;与英国牛津大学、伯明翰大学、韩国SK集团共建国际联合研究中心;与世界经济论坛(达沃斯论坛)、全球大学领导者论坛(GULF)、国际公立大学联盟(IFPU)、国际大学联合会(IAU)、世界工程组织联合会(WFEO)等国际组织保持着密切联系,通过积极参与各类国际组织活动,进一步推动与世界一流大学、机构的实质性、深层次合作。
南开大学先后授予数学家陈省身、物理学家吴大猷、经济学家扬·米尔达尔、美国科学院院士蒋-卡洛·若塔、哈佛大学医学院教授摩斯·居达·福克曼、台湾海基会前董事长江丙坤、美国莱斯大学校长李达伟、世界经济论坛主席克劳斯·施瓦布、新加坡总统陈庆炎、法国宪法委员会主席洛朗·法比尤斯等10位国际著名人士名誉博士称号。诺贝尔奖获得者杨振宁、李政道、罗伯特·蒙代尔、彼得·杜赫提、卡尔·巴里·夏普莱斯、弗农·洛马克斯·史密斯、罗伯特·恩格尔、巴里·詹姆斯·马歇尔、托马斯·萨金特,美国前国务卿基辛格,韩国前总统金大中,欧盟委员会前主席、意大利前总理罗马诺·普罗迪,著名作家金庸等被聘为名誉教授,一批海内外知名学者、著名政治家、企业家任客座教授、兼职教授。
南开大学将深入贯彻落实习近平总书记来校视察重要讲话精神,全面贯彻党的教育方针,坚持社会主义办学方向,落实立德树人根本任务,践行“四个服务”重要使命,加快建设南开品格、中国特色、世界一流大学,培养德智体美劳全面发展的社会主义建设者和接班人,为实现中华民族伟大复兴做出新一代南开人的历史贡献。
(数据截至2020年12月)
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